Handover method, apparatus, and system

ABSTRACT

This application discloses a handover method to hand over relay UE and remote UE between different eNBs. The handover method includes: a source eNB determines based on a measurement report of the relay UE, to hand over the relay UE to a target eNB; sends a first handover required message to a source MME of the relay UE and sends a second handover required message to a source MME of the remote UE; the source MME sends a mobility management context of the remote UE and a mobility management context of the relay UE to a target MME to which the target eNB belongs; the target MME receives a redirection request message from the source MME; and sends information about the remote UE and information about the relay UE to the target eNB.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of International Application No.PCT/CN2018/090696, filed on Jun. 11, 2018, which claims priority toChinese Patent Application No. 201710465053.4, filed on Jun. 19, 2017,the disclosures of which are incorporated herein by reference in theirentireties.

TECHNICAL FIELD

This application relates to the communications field, and in particular,to a handover method, an apparatus, and a system.

BACKGROUND

In a long term evolution wearable (LTE-W) protocol, remote userequipment (UE) (for example, a wearable device (WD)) is connected to acellular network by using relay user equipment. The remote userequipment is usually relatively close to the relay user equipment.Therefore, the remote user equipment may send and receive data atrelatively low power by using the relay user equipment, and the powermay be less than that consumed when the remote user equipment isdirectly connected to the cellular network. The remote UE establishes anS1 application protocol (S1-AP) signaling plane and an S1 user (S1-U)bearer data plane of the remote UE, but communicates with an evolvedNodeB (eNB) by using a radio bearer of the relay UE.

In an existing evolved packet system (EPS) architecture, an eNB mayobtain radio link information of UE, and hand over the UE based on theradio link information. In a wearable scenario, both the remote UE andthe relay UE are movable. Therefore, a problem of handover of the relayUE or the remote UE between different eNBs may exist. However, how theremote UE and the relay UE are handed over in the wearable scenario isnot disclosed in the prior art.

SUMMARY

Embodiments of this application provide a handover method, an apparatus,and a system, to hand over relay UE and remote UE between differenteNBs.

To achieve the foregoing objective, the following technical solutionsare used in the embodiments of this application.

According to a first aspect, a handover method is provided. The methodincludes: when remote user equipment (UE) communicates with a networkside by using relay UE, determining, by a source evolved NodeB (eNB)serving both the remote UE and the relay UE based on a measurementreport of the relay UE, to hand over the relay UE to a target eNB; andwhen a source mobility management entity (MME) of the remote UE is thesame as a source MME of the relay UE, sending, by the source eNB, afirst handover required message to the source MME of the relay UE, wherethe first handover required message includes identifier information ofthe relay UE and identifier information of the remote UE, and the firsthandover required message is used to instruct to hand over both therelay UE and the remote UE to the target eNB; or when a source MME ofthe remote UE is different from a source MME of the relay UE, sending,by the source eNB, a second handover required message to the source MMEof the remote UE, where the second handover request includes identifierinformation of the relay UE, and the second handover required message isused to instruct to hand over the remote UE to the target eNB andassociate the remote UE with relay UE corresponding to an identifier ofthe relay UE. According to the handover method provided in thisembodiment of this application, the remote UE communicates with thenetwork side by using the relay UE, the source eNB serving both theremote UE and the relay UE determines, based on the measurement reportof the relay UE, to hand over the relay UE to the target eNB, and alsoneeds to hand over the remote UE to the target eNB. In a manner, whenthe source MME of the remote UE is the same as the source MME of therelay UE, the source eNB sends the first handover required message tothe source MME of the relay UE, where the first handover requiredmessage includes the identifier information of the relay UE and theidentifier information of the remote UE, to instruct to hand over boththe relay UE and the remote UE to the target eNB; or when the source MMEof the remote UE is different from the source MME of the relay UE, thesource eNB sends the second handover required message to the source MMEof the remote UE, where the second handover request includes theidentifier information of the relay UE, so that the remote UE is, afterhanded over to the target eNB, associated with the relay UEcorresponding to the identifier of the relay UE. In one embodiment,there is no need to determine whether the source MMEs are the same. Thesource eNB sends the first handover required message to the source MMEof the relay UE, where the first handover required message is used toinstruct to hand over the relay UE to the target eNB; and the source eNBsends the second handover required message to the source MME of theremote UE, where the second handover request includes the identifierinformation of the relay UE, and the second handover required message isused to instruct to hand over the remote UE to the target eNB andassociate the remote UE with the relay UE corresponding to theidentifier of the relay UE. In one embodiment, the source MME sends amobility management context of the remote UE and a mobility managementcontext of the relay UE to a target MME to which the target eNB belongs,to hand over both the remote UE and the relay UE to the target eNB. Inone embodiment, the source MME sends a redirection request message to atarget MME to which the target eNB belongs, where the redirectionrequest message includes a mobility management context of the remote UEand the identifier information of the relay UE, to hand over the remoteUE to the target eNB and associate the remote UE with the relay UE. Inone embodiment, the target MME sends information about the remote UE andinformation about the relay UE to the target eNB, to instruct to handover both the relay UE and the remote UE to the target eNB and enablethe target eNB to associate the remote UE with the relay UE. In oneembodiment, the target MME sends a handover request message to thetarget eNB, where the handover request message includes informationabout the remote UE and the identifier information of the relay UE, andthe handover request message is used to instruct to hand over the remoteUE to the target eNB and associate the remote UE with the relay UEcorresponding to the identifier information of the relay UE. S1 handoverof both the remote UE and the relay UE between the eNBs is implementedby using the foregoing communication processes.

In one embodiment, the first handover required message includes grouphandover indication information, and the group handover indicationinformation is used to instruct to hand over both the relay UE and theremote UE to the target eNB. Alternatively, a message header of thefirst handover required message includes a message type, and the messagetype is used to instruct to hand over both the relay UE and the remoteUE to the target eNB. This embodiment provides a manner of instructingto hand over both the relay UE and the remote UE.

In one embodiment, the identifier information of the relay UE includesat least one of the following: a globally unique temporary UE identity(GUTI), a system architecture evolution (SAE)-temporary mobilesubscriber identity (S-TMSI), an MME-temporary mobile subscriberidentity (M-TMSI), and a UE S1 application protocol (S1-AP) identity.This embodiment provides an indication manner of the identifierinformation of the relay UE.

According to a second aspect, a handover method is provided. The methodincludes: when remote user equipment (UE) communicates with a networkside by using relay UE, determining, by a source evolved NodeB (eNB)serving both the remote UE and the relay UE based on a measurementreport of the relay user equipment UE, to hand over the relay UE to atarget eNB; sending, by the source eNB, a first handover requiredmessage to a source MME of the relay UE, where the first handoverrequired message is used to instruct to hand over the relay UE to thetarget eNB; and sending, by the source eNB, a second handover requiredmessage to a source MME of the remote UE, where the second handoverrequest includes identifier information of the relay UE, and the secondhandover required message is used to instruct to hand over the remote UEto the target eNB and associate the remote UE with relay UEcorresponding to an identifier of the relay UE. According to thehandover method provided in this embodiment of this application, theremote UE communicates with the network side by using the relay UE, thesource eNB serving both the remote UE and the relay UE determines, basedon the measurement report of the relay UE, to hand over the relay UE tothe target eNB, and also needs to hand over the remote UE to the targeteNB. In one embodiment, when the source MME of the remote UE is the sameas the source MME of the relay UE, the source eNB sends the firsthandover required message to the source MME of the relay UE, where thefirst handover required message includes the identifier information ofthe relay UE and identifier information of the remote UE, to instruct tohand over both the relay UE and the remote UE to the target eNB; or whenthe source MME of the remote UE is different from the source MME of therelay UE, the source eNB sends the second handover required message tothe source MME of the remote UE, where the second handover requestincludes the identifier information of the relay UE, so that the remoteUE is, after handed over to the target eNB, associated with the relay UEcorresponding to the identifier of the relay UE. In one embodiment,there is no need to determine whether the source MMEs are the same. Thesource eNB sends the first handover required message to the source MMEof the relay UE, where the first handover required message is used toinstruct to hand over the relay UE to the target eNB; and the source eNBsends the second handover required message to the source MME of theremote UE, where the second handover request includes the identifierinformation of the relay UE, and the second handover required message isused to instruct to hand over the remote UE to the target eNB andassociate the remote UE with the relay UE corresponding to theidentifier of the relay UE. In one embodiment, the source MME sends amobility management context of the remote UE and a mobility managementcontext of the relay UE to a target MME to which the target eNB belongs,to hand over both the remote UE and the relay UE to the target eNB. Inone embodiment, the source MME sends a redirection request message to atarget MME to which the target eNB belongs, where the redirectionrequest message includes a mobility management context of the remote UEand the identifier information of the relay UE, to hand over the remoteUE to the target eNB and associate the remote UE with the relay UE. Inone embodiment, the target MME sends information about the remote UE andinformation about the relay UE to the target eNB, to instruct to handover both the relay UE and the remote UE to the target eNB and enablethe target eNB to associate the remote UE with the relay UE. In oneembodiment, the target MME sends a handover request message to thetarget eNB, where the handover request message includes informationabout the remote UE and the identifier information of the relay UE, andthe handover request message is used to instruct to hand over the remoteUE to the target eNB and associate the remote UE with the relay UEcorresponding to the identifier information of the relay UE. S1 handoverof both the remote UE and the relay UE between the eNBs is implementedby using the foregoing communication processes.

In one embodiment, the identifier information of the relay UE includesat least one of the following: a globally unique temporary UE identity(GUTI), a system architecture evolution (SAE)-temporary mobilesubscriber identity (S-TMSI), an MME-temporary mobile subscriberidentity (M-TMSI), and a UE S1 application protocol (S1-AP) identity.This embodiment provides an indication manner of the identifierinformation of the relay UE.

According to a third aspect, a handover method is provided. The methodincludes: receiving, by a source mobility management entity (MME), ahandover required message from a source evolved NodeB (eNB) serving bothrelay user equipment (UE) and remote UE, where the remote UEcommunicates with a network side by using the relay UE, the handoverrequest includes identifier information of the relay UE and identifierinformation of the remote UE, and the handover required message is usedto instruct to hand over both the relay UE and the remote UE to a targeteNB; and sending, by the source MME, a mobility management context ofthe remote UE and a mobility management context of the relay UE to atarget MME to which the target eNB belongs, to hand over both the remoteUE and the relay UE to the target eNB. According to the handover methodprovided in this embodiment of this application, the remote UEcommunicates with the network side by using the relay UE, the source eNBserving both the remote UE and the relay UE determines, based on ameasurement report of the relay UE, to hand over the relay UE to thetarget eNB, and also needs to hand over the remote UE to the target eNB.In one embodiment, when a source MME of the remote UE is the same as asource MME of the relay UE, the source eNB sends a first handoverrequired message to the source MME of the relay UE, where the firsthandover required message includes the identifier information of therelay UE and the identifier information of the remote UE, to instruct tohand over both the relay UE and the remote UE to the target eNB; or whena source MME of the remote UE is different from a source MME of therelay UE, the source eNB sends a second handover required message to thesource MME of the remote UE, where the second handover request includesthe identifier information of the relay UE, so that the remote UE is,after handed over to the target eNB, associated with relay UEcorresponding to an identifier of the relay UE. In one embodiment, thereis no need to determine whether source MMES are the same. The source eNBsends a first handover required message to a source MME of the relay UE,where the first handover required message is used to instruct to handover the relay UE to the target eNB; and the source eNB sends a secondhandover required message to a source MME of the remote UE, where thesecond handover request includes the identifier information of the relayUE, and the second handover required message is used to instruct to handover the remote UE to the target eNB and associate the remote UE withrelay UE corresponding to an identifier of the relay UE. In oneembodiment, the source MME sends the mobility management context of theremote UE and the mobility management context of the relay UE to thetarget MME to which the target eNB belongs, to hand over both the remoteUE and the relay UE to the target eNB. In one embodiment, the source MMEsends a redirection request message to the target MME to which thetarget eNB belongs, where the redirection request message includes themobility management context of the remote UE and the identifierinformation of the relay UE, to hand over the remote UE to the targeteNB and associate the remote UE with the relay UE. In one embodiment,the target MME sends information about the remote UE and informationabout the relay UE to the target eNB, to instruct to hand over both therelay UE and the remote UE to the target eNB and enable the target eNBto associate the remote UE with the relay UE. In one embodiment, thetarget MME sends a handover request message to the target eNB, where thehandover request message includes information about the remote UE andthe identifier information of the relay UE, and the handover requestmessage is used to instruct to hand over the remote UE to the target eNBand associate the remote UE with the relay UE corresponding to theidentifier information of the relay UE. S1 handover of both the remoteUE and the relay UE between the eNBs is implemented by using theforegoing communication processes.

In one embodiment, the sending, by the source MME, a mobility managementcontext of the remote UE and a mobility management context of the relayUE to a target MME to which the target eNB belongs, to hand over boththe remote UE and the relay UE to the target eNB includes: sending, bythe source MME, a first redirection request message to the target MME,where the first redirection request message includes the mobilitymanagement context of the relay UE and the mobility management contextof the remote UE, to hand over both the remote UE and the relay UE tothe target eNB. This embodiment provides a manner of simultaneouslysending the mobility management context of the relay UE and the mobilitymanagement context of the remote UE.

In one embodiment, the sending, by the source MME, a mobility managementcontext of the remote UE and a mobility management context of the relayUE to a target MME to which the target eNB belongs, to hand over boththe remote UE and the relay UE to the target eNB includes: sending, by afirst source MME, a second redirection request message to the targetMME, where the second redirection request message includes the mobilitymanagement context of the relay UE; and sending, by a second source MME,a third redirection request message to the target MME, where the thirdredirection request message includes the mobility management context ofthe remote UE and the identifier information of the relay UE, to handover the remote UE to the target eNB and associate the remote UE withthe relay UE corresponding to the identifier of the relay UE. The firstsource MME and the second source MME are a same MME or different MMEs.This embodiment provides a manner of separately sending the mobilitymanagement context of the relay UE and the mobility management contextof the remote UE.

In one embodiment, the method further includes: obtaining, by the secondsource MIME, second identifier information of the relay UE in the thirdredirection request message based on first identifier information of therelay UE in the handover required message. According to this embodiment,the identifier information of the relay UE may be directly transferredor indirectly obtained.

According to a fourth aspect, a handover method is provided. The methodincludes: receiving, by a source mobility management entity (MME), ahandover required message from a source evolved NodeB (eNB) serving bothrelay user equipment (UE) and remote UE, where the remote UEcommunicates with a network side by using the relay UE, the handoverrequest includes identifier information of the relay UE, the handoverrequired message is used to instruct to hand over the remote UE to atarget eNB and associate the remote UE with relay UE corresponding to anidentifier of the relay UE, and the target eNB is an eNB to which therelay UE is to be handed over; and sending, by the source MME, aredirection request message to a target MME to which the target eNBbelongs, where the redirection request message includes a mobilitymanagement context of the remote UE and the identifier information ofthe relay UE, to hand over the remote UE to the target eNB and associatethe remote UE with the relay UE. According to the handover methodprovided in this embodiment of this application, the remote UEcommunicates with the network side by using the relay UE, the source eNBserving both the remote UE and the relay UE determines, based on ameasurement report of the relay UE, to hand over the relay UE to thetarget eNB, and also needs to hand over the remote UE to the target eNB.In one embodiment, when a source MME of the remote UE is the same as asource MME of the relay UE, the source eNB sends a first handoverrequired message to the source MME of the relay UE, where the firsthandover required message includes the identifier information of therelay UE and identifier information of the remote UE, to instruct tohand over both the relay UE and the remote UE to the target eNB; or whena source MME of the remote UE is different from a source MME of therelay UE, the source eNB sends a second handover required message to thesource MME of the remote UE, where the second handover request includesthe identifier information of the relay UE, so that the remote UE is,after handed over to the target eNB, associated with relay UEcorresponding to an identifier of the relay UE. In one embodiment, thereis no need to determine whether source MMES are the same. The source eNBsends a first handover required message to a source MME of the relay UE,where the first handover required message is used to instruct to handover the relay UE to the target eNB; and the source eNB sends a secondhandover required message to a source MME of the remote UE, where thesecond handover request includes the identifier information of the relayUE, and the second handover required message is used to instruct to handover the remote UE to the target eNB and associate the remote UE withrelay UE corresponding to an identifier of the relay UE. In oneembodiment, the source MME sends the mobility management context of theremote UE and a mobility management context of the relay UE to thetarget MME to which the target eNB belongs, to hand over both the remoteUE and the relay UE to the target eNB. In one embodiment, the source MMEsends the redirection request message to the target MME to which thetarget eNB belongs, where the redirection request message includes themobility management context of the remote UE and the identifierinformation of the relay UE, to hand over the remote UE to the targeteNB and associate the remote UE with the relay UE. In one embodiment,the target MME sends information about the remote UE and informationabout the relay UE to the target eNB, to instruct to hand over both therelay UE and the remote UE to the target eNB and enable the target eNBto associate the remote UE with the relay UE. In one embodiment, thetarget MME sends a handover request message to the target eNB, where thehandover request message includes information about the remote UE andthe identifier information of the relay UE, and the handover requestmessage is used to instruct to hand over the remote UE to the target eNBand associate the remote UE with the relay UE corresponding to theidentifier information of the relay UE. S1 handover of both the remoteUE and the relay UE between the eNBs is implemented by using theforegoing communication processes.

In one embodiment, the method further includes: obtaining, by the sourceMME, second identifier information of the relay UE in the redirectionrequest message based on first identifier information of the relay UE inthe handover required message. According to this embodiment, theidentifier information of the relay UE may be directly transferred orindirectly obtained.

According to a fifth aspect, a handover method is provided. The methodincludes: receiving, by a target mobility management entity (MME), aredirection request message from a source MME, where the redirectionrequest message includes a mobility management context of remote userequipment (UE) and a mobility management context of relay UE, toinstruct to hand over both the relay UE and the remote UE to a targetevolved NodeB (eNB), the remote UE communicates with a network side byusing the relay UE, and the target MME is an MME to which the target eNBbelongs; and sending, by the target MME, information about the remote UEand information about the relay UE to the target eNB, to instruct tohand over both the relay UE and the remote UE to the target eNB andenable the target eNB to associate the remote UE with the relay UE.According to the handover method provided in this embodiment of thisapplication, the remote UE communicates with a network side by using therelay UE, a source eNB serving both the remote UE and the relay UEdetermines, based on a measurement report of the relay UE, to hand overthe relay UE to the target eNB, and also needs to hand over the remoteUE to the target eNB. In one embodiment, when a source MME of the remoteUE is the same as a source MME of the relay UE, the source eNB sends afirst handover required message to the source MME of the relay UE, wherethe first handover required message includes identifier information ofthe relay UE and identifier information of the remote UE, to instruct tohand over both the relay UE and the remote UE to the target eNB; or whena source MME of the remote UE is different from a source MME of therelay UE, the source eNB sends a second handover required message to thesource MME of the remote UE, where the second handover request includesidentifier information of the relay UE, so that the remote UE is, afterhanded over to the target eNB, associated with relay UE corresponding toan identifier of the relay UE. In one embodiment, there is no need todetermine whether source MMES are the same. The source eNB sends a firsthandover required message to a source MME of the relay UE, where thefirst handover required message is used to instruct to hand over therelay UE to the target eNB; and the source eNB sends a second handoverrequired message to a source MME of the remote UE, where the secondhandover request includes identifier information of the relay UE, andthe second handover required message is used to instruct to hand overthe remote UE to the target eNB and associate the remote UE with relayUE corresponding to an identifier of the relay UE. In one embodiment,the source MME sends the mobility management context of the remote UEand the mobility management context of the relay UE to the target MME towhich the target eNB belongs, to hand over both the remote UE and therelay UE to the target eNB. In one embodiment, the source MME sends theredirection request message to the target MME to which the target eNBbelongs, where the redirection request message includes the mobilitymanagement context of the remote UE and the identifier information ofthe relay UE, to hand over the remote UE to the target eNB and associatethe remote UE with the relay UE. In one embodiment, the target MME sendsthe information about the remote UE and the information about the relayUE to the target eNB, to instruct to hand over both the relay UE and theremote UE to the target eNB and enable the target eNB to associate theremote UE with the relay UE. In one embodiment, the target MME sends ahandover request message to the target eNB, where the handover requestmessage includes the information about the remote UE and the identifierinformation of the relay UE, and the handover request message is used toinstruct to hand over the remote UE to the target eNB and associate theremote UE with the relay UE corresponding to the identifier informationof the relay UE. S1 handover of both the remote UE and the relay UEbetween the eNBs is implemented by using the foregoing communicationprocesses.

In one embodiment, the sending, by the target MME, information about theremote UE and information about the relay UE to the target eNB, toinstruct to hand over both the relay UE and the remote UE to the targeteNB and enable the target eNB to associate the remote UE with the relayUE includes: sending, by the target MME, a first handover requestmessage to the target eNB, where the first handover request messageincludes the information about the remote UE and the information aboutthe relay UE, and the first handover request message is used to instructto hand over both the relay UE and the remote UE to the target eNB andenable the target eNB to associate the remote UE with the relay UE. Thisembodiment provides a manner of simultaneously sending the informationabout the remote UE and the information about the relay UE.

In one embodiment, the sending, by the target MME, information about theremote UE and information about the relay UE to the target eNB, toinstruct to hand over both the relay UE and the remote UE to the targeteNB and enable the target eNB to associate the remote UE with the relayUE includes: sending, by a first target MME, a second handover requestmessage to the target eNB, where the second handover request messageincludes the information about the relay UE; and sending, by a secondtarget MME, a third handover request message to the target eNB, wherethe third handover request message includes the information about theremote UE and the identifier information of the relay UE, and the thirdhandover request message is used to instruct to hand over the remote UEto the target eNB and associate the remote UE with the relay UEcorresponding to the identifier information of the relay UE. The firsttarget MME and the second target MME are a same MME or different MMES.This embodiment provides a manner of separately sending the informationabout the remote UE and the information about the relay UE.

According to a sixth aspect, a handover method is provided. The methodincludes: receiving, by a target mobility management entity (MME), aredirection request message from a source MME, where the redirectionrequest message is used to instruct to hand over remote user equipment(UE) to a target evolved NodeB (eNB), the target eNB is an eNB to whichrelay UE is to be handed over, the remote UE communicates with a networkside by using the relay UE, the target MME is an MME to which the targeteNB belongs, and the redirection request message includes a mobilitymanagement context of the remote UE and identifier information of therelay UE; and sending, by the target MME, a handover request message tothe target eNB, where the handover request message includes informationabout the remote UE and the identifier information of the relay UE, andthe handover request message is used to instruct to hand over the remoteUE to the target eNB and associate the remote UE with relay UEcorresponding to the identifier information of the relay UE. Accordingto the handover method provided in this embodiment of this application,the remote UE communicates with the network side by using the relay UE,a source eNB serving both the remote UE and the relay UE determines,based on a measurement report of the relay UE, to hand over the relay UEto the target eNB, and also needs to hand over the remote UE to thetarget eNB. In one embodiment, when a source MME of the remote UE is thesame as a source MME of the relay UE, the source eNB sends a firsthandover required message to the source MME of the relay UE, where thefirst handover required message includes the identifier information ofthe relay UE and identifier information of the remote UE, to instruct tohand over both the relay UE and the remote UE to the target eNB; or whena source MME of the remote UE is different from a source MME of therelay UE, the source eNB sends a second handover required message to thesource MME of the remote UE, where the second handover request includesthe identifier information of the relay UE, so that the remote UE is,after handed over to the target eNB, associated with the relay UEcorresponding to the identifier of the relay UE. In one embodiment,there is no need to determine whether source MMES are the same. Thesource eNB sends a first handover required message to a source MME ofthe relay UE, where the first handover required message is used toinstruct to hand over the relay UE to the target eNB; and the source eNBsends a second handover required message to a source MME of the remoteUE, where the second handover request includes the identifierinformation of the relay UE, and the second handover required message isused to instruct to hand over the remote UE to the target eNB andassociate the remote UE with the relay UE corresponding to theidentifier of the relay UE. In one embodiment, the source MME sends themobility management context of the remote UE and a mobility managementcontext of the relay UE to the target MME to which the target eNBbelongs, to hand over both the remote UE and the relay UE to the targeteNB. In another manner, the source MME sends the redirection requestmessage to the target MME to which the target eNB belongs, where theredirection request message includes the mobility management context ofthe remote UE and the identifier information of the relay UE, to handover the remote UE to the target eNB and associate the remote UE withthe relay UE. In one embodiment, the target MME sends the informationabout the remote UE and information about the relay UE to the targeteNB, to instruct to hand over both the relay UE and the remote UE to thetarget eNB and enable the target eNB to associate the remote UE with therelay UE. In one embodiment, the target MME sends the handover requestmessage to the target eNB, where the handover request message includesthe information about the remote UE and the identifier information ofthe relay UE, and the handover request message is used to instruct tohand over the remote UE to the target eNB and associate the remote UEwith the relay UE corresponding to the identifier information of therelay UE. S1 handover of both the remote UE and the relay UE between theeNBs is implemented by using the foregoing communication processes.

According to a seventh aspect, a source evolved NodeB (eNB) is provided.The source eNB includes: a determining unit, configured to: when remoteuser equipment (UE) communicates with a network side by using relay UE,determine, based on a measurement report of the relay UE, to hand overthe relay UE to a target eNB, where the source eNB is an eNB servingboth the remote UE and the relay UE; and a sending unit, configured to:when a source MME of the remote UE is the same as a source MME of therelay UE, send a first handover required message to the source MME ofthe relay UE, where the first handover required message includesidentifier information of the relay UE and identifier information of theremote UE, and the first handover required message is used to instructto hand over both the relay UE and the remote UE to the target eNB. Thesending unit is further configured to: when the source MME of the remoteUE is different from the source MME of the relay UE, send a secondhandover required message to the source MME of the remote UE, where thesecond handover request includes the identifier information of the relayUE, and the second handover required message is used to instruct to handover the remote UE to the target eNB and associate the remote UE withrelay UE corresponding to an identifier of the relay UE. Based on a sameinventive concept, for a problem-resolving principle and beneficialeffects of the apparatus, refer to the first aspect, the embodiments ofthe method of the first aspect, and the resulting beneficial effects.Therefore, for implementation of the apparatus, refer to the firstaspect and the embodiments of the method of the first aspect. Detailsare not described herein again.

According to an eighth aspect, a source evolved NodeB (eNB) is provided.The source eNB includes: a determining unit, configured to: when remoteuser equipment (UE) communicates with a network side by using relay UE,determine, based on a measurement report of the relay user equipment UE,to hand over the relay UE to a target eNB, where the source eNB is aneNB serving both the remote UE and the relay UE; and a sending unit,configured to send a first handover required message to a source MME ofthe relay UE, where the first handover required message is used toinstruct to hand over the relay UE to the target eNB. The sending unitis further configured to send a second handover required message to asource MME of the remote UE, where the second handover request includesidentifier information of the relay UE, and the second handover requiredmessage is used to instruct to hand over the remote UE to the target eNBand associate the remote UE with relay UE corresponding to an identifierof the relay UE. Based on a same inventive concept, for aproblem-resolving principle and beneficial effects of the apparatus,refer to the second aspect, the embodiments of the method of the secondaspect, and the resulting beneficial effects. Therefore, forimplementation of the apparatus, refer to the second aspect and theembodiments of the method of the second aspect Details are not describedherein again.

According to a ninth aspect, a source mobility management entity (MME)is provided. The source MME includes: a receiving unit, configured toreceive a handover required message from a source evolved NodeB (eNB)serving both relay user equipment (UE) and remote UE, where the remoteUE communicates with a network side by using the relay UE, the handoverrequest includes identifier information of the relay UE and identifierinformation of the remote UE, and the handover required message is usedto instruct to hand over both the relay UE and the remote UE to a targeteNB; and a sending unit, configured to send a mobility managementcontext of the remote UE and a mobility management context of the relayUE to a target MME to which the target eNB belongs, to hand over boththe remote UE and the relay UE to the target eNB. Based on a sameinventive concept, for a problem-resolving principle and beneficialeffects of the apparatus, refer to the third aspect, the embodiments ofthe method of the third aspect, and the resulting beneficial effects.Therefore, for implementation of the apparatus, refer to the thirdaspect and the embodiments of the method of the third aspect. Detailsare not described herein again.

According to a tenth aspect, a source mobility management entity (MME)is provided. The source MME includes: a receiving unit, configured toreceive a handover required message from a source evolved NodeB (eNB)serving both relay user equipment (UE) and remote UE, where the remoteUE communicates with a network side by using the relay UE, the handoverrequest includes identifier information of the relay UE, the handoverrequired message is used to instruct to hand over the remote UE to atarget eNB and associate the remote UE with relay UE corresponding to anidentifier of the relay UE, and the target eNB is an eNB to which therelay UE is to be handed over; and a sending unit, configured to send aredirection request message to a target MME to which the target eNBbelongs, where the redirection request message includes a mobilitymanagement context of the remote UE and the identifier information ofthe relay UE, to hand over the remote UE to the target eNB and associatethe remote UE with the relay UE. Based on a same inventive concept, fora problem-resolving principle and beneficial effects of the apparatus,refer to the fourth aspect, the embodiments of the method of the fourthaspect, and the resulting beneficial effects. Therefore, forimplementation of the apparatus, refer to the fourth aspect and theembodiments of the method of the fourth aspect. Details are notdescribed herein again.

According to an eleventh aspect, a target mobility management entity(MME) is provided. The target MME includes: a receiving unit, configuredto receive a redirection request message from a source MME, where theredirection request message includes a mobility management context ofremote user equipment (UE) and a mobility management context of relayUE, to instruct to hand over both the relay UE and the remote UE to atarget evolved NodeB (eNB), the remote UE communicates with a networkside by using the relay UE, and the target MME is an MME to which thetarget eNB belongs; and a sending unit, configured to send informationabout the remote UE and information about the relay UE to the targeteNB, to instruct to hand over both the relay UE and the remote UE to thetarget eNB and enable the target eNB to associate the remote UE with therelay UE. Based on a same inventive concept, for a problem-resolvingprinciple and beneficial effects of the apparatus, refer to the fifthaspect, the embodiments of the method of the fifth aspect, and theresulting beneficial effects. Therefore, for implementation of theapparatus, refer to the fifth aspect and the embodiments of the methodof the fifth aspect. Details are not described herein again.

According to a twelfth aspect, a target mobility management entity (MME)is provided. The target MME includes: a receiving unit, configured toreceive a redirection request message from a source MME, where theredirection request message is used to instruct to hand over remote userequipment (UE) to a target evolved NodeB (eNB), the target eNB is an eNBto which relay UE is to be handed over, the remote UE communicates witha network side by using the relay UE, the target MME is an MME to whichthe target eNB belongs, and the redirection request message includes amobility management context of the remote UE and identifier informationof the relay UE; and a sending unit, configured to send a handoverrequest message to the target eNB, where the handover request messageincludes information about the remote UE and the identifier informationof the relay UE, and the handover request message is used to instruct tohand over the remote UE to the target eNB and associate the remote UEwith relay UE corresponding to the identifier information of the relayUE. Based on a same inventive concept, for a problem-resolving principleand beneficial effects of the apparatus, refer to the sixth aspect, theembodiments of the method of the sixth aspect, and the resultingbeneficial effects. Therefore, for implementation of the apparatus,refer to the sixth aspect and the embodiments of the method of the sixthaspect. Details are not described herein again.

According to a thirteenth aspect, a source evolved NodeB eNB isprovided. The source eNB includes: a processor, a memory, a bus, and acommunications interface. The memory is configured to store a computerexecutable instruction. The processor is connected to the memory via thebus. When the source eNB runs, the processor executes the computerexecutable instruction stored in the memory, so that the source eNBperforms the method according to any one of the first aspect and theembodiments of the first aspect, or performs the method according to anyone of the second aspect and the embodiments of the second aspect.

According to a fourteenth aspect, a source mobility management entityMME is provided. The source MME includes: a processor, a memory, a bus,and a communications interface. The memory is configured to store acomputer executable instruction. The processor is connected to thememory via the bus. When the source MME runs, the processor executes thecomputer executable instruction stored in the memory, so that the sourceMME performs the method according to any one of the third aspect and theembodiments of the third aspect, or performs the method according to anyone of the fourth aspect and the embodiments of the fourth aspect.

According to a fifteenth aspect, a target mobility management entity MMEis provided. The target MME includes: a processor, a memory, a bus, anda communications interface. The memory is configured to store a computerexecutable instruction. The processor is connected to the memory via thebus. When the target MME runs, the processor executes the computerexecutable instruction stored in the memory, so that the target MMEperforms the method according to any one of the fifth aspect and theembodiments of the fifth aspect, or performs the method according to anyone of the sixth aspect and the embodiments of the sixth aspect.

According to a sixteenth aspect, a computer storage medium is provided.The computer storage medium includes an instruction, and when theinstruction is run on a computer, the computer is enabled to perform themethod according to any one of the first aspect and the embodiments ofthe first aspect, or to perform the method according to any one of thesecond aspect and the embodiments of the second aspect.

According to a seventeenth aspect, a computer storage medium isprovided. The computer storage medium includes an instruction, and whenthe instruction is run on a computer, the computer is enabled to performthe method according to any one of the third aspect and the embodimentsof the third aspect, or to perform the method according to any one ofthe fourth aspect and the embodiments of the fourth aspect.

According to an eighteenth aspect, a computer storage medium isprovided. The computer storage medium includes an instruction, and whenthe instruction is run on a computer, the computer is enabled to performthe method according to any one of the fifth aspect and the embodimentsof the fifth aspect, or to perform the method according to any one ofthe sixth aspect and the embodiments of the sixth aspect.

According to a nineteenth aspect, a computer program product includingan instruction is provided. When the computer program product is run ona computer, the computer is enabled to perform the method according toany one of the first aspect and the embodiments of the first aspect, orto perform the method according to any one of the second aspect and theembodiments of the second aspect.

According to a twentieth aspect, a computer program product including aninstruction is provided. When the computer program product is run on acomputer, the computer is enabled to perform the method according to anyone of the third aspect and the embodiments of the third aspect, or toperform the method according to any one of the fourth aspect and theembodiments of the fourth aspect.

According to a twenty-first aspect, a computer program product includingan instruction is provided. When the computer program product is run ona computer, the computer is enabled to perform the method according toany one of the fifth aspect and the embodiments of the fifth aspect, orto perform the method according to any one of the sixth aspect and theembodiments of the sixth aspect.

According to a twenty-second aspect, a communications system isprovided. The communications system includes the source evolved NodeB(eNB) according to the seventh aspect or the source eNB according to theeighth aspect, the source mobility management entity (MME) according tothe ninth aspect or the source MME according to the tenth aspect, andthe target (MME) according to the eleventh aspect or the target MMEaccording to the twelfth aspect; or includes the source eNB according tothe thirteenth aspect, the source MME according to the fourteenthaspect, and the target MME according to the fifteenth aspect.

It should be noted that, for technical effects brought in the thirteenthaspect to the twenty-second aspect, refer to the technical effectsbrought by corresponding methods. Details are not described hereinagain.

According to a twenty-third aspect, a handover method is provided. Themethod includes: determining, by a source evolved NodeB (eNB) based on ameasurement report of relay user equipment (relay UE) and depending onwhether there is remote user equipment (remote UE) communicating withthe source eNB by using the relay UE, whether to hand over both therelay UE and the remote UE to a target eNB; when determining to handover both the relay UE and the remote UE to the target eNB, sending, bythe source eNB, handover information of the relay UE and handoverinformation of the remote UE to the target eNB, to initiate handover tothe target eNB, where the handover information of the relay UE includesa context of the relay UE, and the handover information of the remote UEincludes a context of the remote UE; receiving, by the source eNB, firstaccess information and second access information from the target eNB,where the first access information is obtained by the target eNB basedon the handover information of the relay UE, so that the relay UE ishanded over and accesses the target eNB, and the second accessinformation is obtained by the target eNB based on the handoverinformation of the remote UE, so that the remote UE is handed over andaccesses the target eNB by using the relay UE; sending, by the sourceeNB, the first access information and the second access information tothe relay UE, so that the relay UE forwards the second accessinformation to the remote UE; receiving, by the source eNB, releaseindication information from the target eNB, where the release indicationinformation is used to instruct the source eNB to release the context ofthe relay UE and the context of the remote UE; and releasing, by thesource eNB, the context of the relay UE and the context of the remote UEaccording to the release indication information. According to thehandover method provided in this embodiment of this application, whenthe source eNB initiates to hand over both the remote UE and the relayUE to the target eNB, the handover information of the remote UE and thehandover information of the relay UE are carried, and include thecontext of the remote UE and the context of the relay UE. The target eNBobtains the access information of the remote UE and the accessinformation of the relay UE based on the handover information of theremote UE and the handover information of the relay UE, and the sourceeNB forwards the access information to the remote UE and the relay UE,so that the remote UE and the relay UE access the target eNB based onrespective access information. After the remote UE and the relay UE aresuccessfully handed over and access a target eNB, the target eNBinstructs the source eNB to release the context of the remote UE and thecontext of the relay UE. The context of the remote UE and the context ofthe relay UE are transferred from the source eNB to the target eNB, andthe remote UE and the relay UE successfully access the target eNB.Therefore, the remote UE and the relay UE are both handed over in awearable scenario.

In one embodiment, the sending, by the source eNB, handover informationof the relay UE and handover information of the remote UE to the targeteNB includes: sending, by the source eNB, a first handover requestmessage to the target eNB, where the first handover request messageincludes the handover information of the relay UE and the handoverinformation of the remote UE. This embodiment provides a manner ofsimultaneously sending the handover information of the relay UE and thehandover information of the remote UE.

In one embodiment, the sending, by the source eNB, handover informationof the relay UE and handover information of the remote UE to the targeteNB includes: sending, by the source eNB, a second handover requestmessage to the target eNB, where the second handover request messageincludes the handover information of the relay UE; and sending, by thesource eNB, a third handover request message to the target eNB, wherethe third handover request message includes the handover information ofthe remote UE. This embodiment provides a manner of separately sendingthe handover information of the relay UE and the handover information ofthe remote UE.

In one embodiment, the handover request message further includes anindication information information-element, and the indicationinformation information-element is used to instruct to hand over boththe relay UE and the remote UE. This embodiment provides a manner ofinstructing to hand over both the relay UE and the remote UE.

In one embodiment, a message type in a message header of the handoverrequest message is used to instruct to hand over both the relay UE andthe remote UE. This embodiment provides another manner of instructing tohand over both the relay UE and the remote UE.

In one embodiment, the sending, by the source eNB, the first accessinformation and the second access information to the relay UE, so thatthe relay UE forwards the second access information to the remote UEincludes: sending, by the source eNB, a first radio resource control(RRC) connection reconfiguration message to the relay UE, so that therelay UE forwards the second access information to the remote UE, wherethe first RRC connection reconfiguration message includes the firstaccess information and the second access information. This embodimentprovides a manner of simultaneously sending the access information ofthe relay UE and the access information of the remote UE.

In one embodiment, the sending, by the source eNB, the first accessinformation and the second access information to the relay UE, so thatthe relay UE forwards the second access information to the remote UEincludes: sending, by the source eNB, a second RRC connectionreconfiguration message to the relay UE, where the second RRC connectionreconfiguration message includes the first access information; andsending, by the source eNB, a third RRC connection reconfigurationmessage to the relay UE, so that the relay UE forwards the second accessinformation to the remote UE, where the third RRC connectionreconfiguration message includes the second access information. Thisembodiment provides a manner of separately sending the accessinformation of the relay UE and the access information of the remote UE.

In one embodiment, the release indication information includes anidentifier of the relay UE, and the releasing, by the source eNB, thecontext of the relay UE and the context of the remote UE according tothe release indication information includes: releasing, by the sourceeNB, the context of the relay UE based on the identifier of the relayUE; obtaining, by the source eNB, an identifier of the remote UE basedon the identifier of the relay UE and an association relationshipbetween the relay UE and the remote UE; and releasing, by the sourceeNB, the context of the remote UE based on the identifier of the remoteUE. This embodiment provides a specific manner of releasing the contextof the UE.

In one embodiment, the release indication information includes anidentifier of the relay UE and an identifier of the remote UE, and thereleasing, by the source eNB, the context of the relay UE and thecontext of the remote UE according to the release indication informationincludes: releasing, by the source eNB, the context of the relay UEbased on the identifier of the relay UE; and releasing, by the sourceeNB, the context of the remote UE based on the identifier of the remoteUE. This embodiment provides a specific manner of releasing the contextof the UE.

In one embodiment, the handover information further includes anassociation relationship between the relay UE and the remote UE. Thisone embodiment provides a specific form of the handover information.

In one embodiment, the handover information further includes anidentifier of the relay UE and an identifier of the remote UE. Thisembodiment provides a specific manner of the handover information.

In one embodiment, the context of the relay UE and/or the context of theremote UE includes an association relationship between the relay UE andthe remote UE. This embodiment provides a specific manner of the contextof the relay UE and/or the context of the remote UE.

In one embodiment, the context of the relay UE includes an identifier ofthe relay UE, and the context of the remote UE includes an identifier ofthe remote UE. This embodiment provides a specific manner of the contextof the relay UE and/or the context of the remote UE.

According to a twenty-fourth aspect, a handover method is provided. Themethod includes: receiving, by a target evolved NodeB (eNB), handoverinformation of relay user equipment (relay UE) and handover informationof remote user equipment (remote UE) from a source eNB, to determinewhether the relay UE and the remote UE are both allowed to be handedover from the source eNB to the target eNB, where the remote UEcommunicates with the source eNB by using the relay UE, the handoverinformation of the relay UE includes a context of the relay UE, and thehandover information of the remote UE includes a context of the remoteUE; when determining that the relay UE and the remote UE are bothallowed to be handed over, obtaining, by the target eNB, first accessinformation based on the handover information of the relay UE, so thatthe relay UE is handed over and accesses the target eNB; obtainingsecond access information based on the handover information of theremote UE, so that the remote UE is handed over and accesses the targeteNB by using the relay UE; sending, by the target eNB, the first accessinformation and the second access information to the source eNB, so thatthe source eNB forwards the first access information to the relay UE andforwards the second access information to the remote UE; receiving, bythe target eNB, a handover success indication of the relay UE and ahandover success indication of the remote UE, where the handover successindication of the relay UE is used to indicate that the relay UE issuccessfully handed over and accesses the target eNB, and the handoversuccess indication of the remote UE is used to indicate that the remoteUE is successfully handed over and accesses the target eNB by using therelay UE; starting, by the target eNB, path switch procedures for therelay UE and the remote UE; and sending, by the target eNB, releaseindication information to the source eNB after determining that therelay UE and the remote UE complete the path switch procedures, wherethe release indication information is used to instruct the source eNB torelease the context of the relay UE and the context of the remote UE.According to the handover method provided in this embodiment of thisapplication, when the source eNB initiates to hand over both the remoteUE and the relay UE to the target eNB, the handover information of theremote UE and the handover information of the relay UE are carried, andinclude the context of the remote UE and the context of the relay UE.The target eNB obtains the access information of the remote UE and theaccess information of the relay UE based on the handover information ofthe remote UE and the handover information of the relay UE, and thesource eNB forwards the access information to the remote UE and therelay UE, so that the remote UE and the relay UE access a target eNBbased on respective access information. After the remote UE and therelay UE are successfully handed over and access the target eNB, thetarget eNB instructs the source eNB to release the context of the remoteUE and the context of the relay UE. The context of the remote UE and thecontext of the relay UE are transferred from the source eNB to thetarget eNB, and the remote UE and the relay UE successfully access thetarget eNB. Therefore, the remote UE and the relay UE are both handedover in a wearable scenario.

In one embodiment, the receiving, by a target evolved NodeB (eNB),handover information of relay user equipment (relay UE) and handoverinformation of remote user equipment (remote UE) from a source eNBincludes: receiving, by the target eNB, a first handover request messagefrom the source eNB, where the first handover request message includesthe handover information of the relay UE and the handover information ofthe remote UE. This embodiment provides a manner of simultaneouslysending the handover information of the relay UE and the handoverinformation of the remote UE.

In one embodiment, the receiving, by a target evolved NodeB (eNB),handover information of relay user equipment (relay UE) and handoverinformation of remote user equipment (remote UE) from a source eNBincludes: receiving, by the target eNB, a second handover requestmessage from the source eNB, where the second handover request messageincludes the handover information of the relay UE; and receiving, by thetarget eNB, a third handover request message from the source eNB, wherethe third handover request message includes the handover information ofthe remote UE. This embodiment provides a manner of separately sendingthe handover information of the relay UE and the handover information ofthe remote UE.

In one embodiment, the handover request message further includeshandover type indication information, and the handover type indicationinformation is used to instruct to hand over both the relay UE and theremote UE. This embodiment provides a manner of instructing to hand overboth the relay UE and the remote UE.

In one embodiment, a message type in a message header of the handoverrequest message is used to instruct to hand over both the relay UE andthe remote UE. This embodiment provides another manner of instructing tohand over both the relay UE and the remote UE.

In one embodiment, the sending, by the target eNB, the first accessinformation and the second access information to the source eNBincludes: sending, by the target eNB, a first handover requestacknowledgment message to the source eNB, where the first handoverrequest acknowledgment message includes the first access information andthe second access information. This embodiment provides a manner ofsimultaneously sending the access information of the relay UE and theaccess information of the remote UE.

In one embodiment, the sending, by the target eNB, the first accessinformation and the second access information to the source eNBincludes: sending, by the target eNB, a second handover requestacknowledgment message to the source eNB, where the second handoverrequest acknowledgment message includes the first access information;and sending, by the target eNB, a third handover request acknowledgmentmessage to the source eNB, where the third handover requestacknowledgment message includes the second access information. Thisembodiment provides a manner of separately sending the accessinformation of the relay UE and the access information of the remote UE.

In one embodiment, the release indication information includes anidentifier of the relay UE, so that the source eNB releases the contextof the relay UE based on the identifier of the relay UE, obtains anidentifier of the remote UE based on the identifier of the relay UE andan association relationship between the relay UE and the remote UE, andreleases the context of the remote UE based on the identifier of theremote UE. This embodiment provides a specific manner of releasing thecontext of the UE.

In one embodiment, the release indication information includes anidentifier of the relay UE and an identifier of the remote UE, so thatthe source eNB releases the context of the relay UE based on theidentifier of the relay UE, and releases the context of the remote UEbased on the identifier of the remote UE. This embodiment provides aspecific manner of releasing the context of the UE.

In one embodiment, the receiving, by the target eNB, a handover successindication of the relay UE and a handover success indication of theremote UE from the relay UE includes: receiving, by the target eNB, afirst RRC connection reconfiguration complete message from the relay UE,where the first RRC connection reconfiguration complete message includesthe handover success indication of the relay UE and the handover successindication of the remote UE. This embodiment provides a manner ofsimultaneously sending by the relay UE and receiving by the target eNBthe handover success indication of the relay UE and the handover successinformation of the relay UE.

In one embodiment, the receiving, by the target eNB, a handover successindication of the relay UE and a handover success indication of theremote UE from the relay UE includes: receiving, by the target eNB, asecond RRC connection reconfiguration complete message from the relayUE, where the second RRC connection reconfiguration complete messageincludes the handover success indication of the relay UE; and receiving,by the target eNB, a third RRC connection reconfiguration completemessage from the relay UE, where the third RRC connectionreconfiguration complete message includes the handover successindication of the remote UE, and the handover success indication of theremote UE is sent by the remote UE to the relay UE. This embodimentprovides a manner of separately sending by the relay UE and receiving bythe target eNB the handover success indication of the relay UE and thehandover success information of the relay UE.

In one embodiment, the handover information further includes anassociation relationship between the relay UE and the remote UE. Thisembodiment provides a specific manner of the handover information.

In one embodiment, the handover information further includes anidentifier of the relay UE and an identifier of the remote UE. Thisembodiment provides a specific manner of the handover information.

In one embodiment, the context of the relay UE and/or the context of theremote UE includes an association relationship between the relay UE andthe remote UE. This embodiment provides a specific manner of the contextof the relay UE and/or the context of the remote UE.

In one embodiment, the context of the relay UE includes an identifier ofthe relay UE, and the context of the remote UE includes an identifier ofthe remote UE. This embodiment provides a specific manner of the contextof the relay UE and/or the context of the remote UE.

According to a twenty-fifth aspect, a source evolved NodeB (eNB) isprovided. The source eNB includes: a determining unit, a sending unit, areceiving unit, and a release unit. The determining unit is configuredto determine, based on a measurement report of relay user equipment(relay UE) and depending on whether there is remote user equipment(remote UE) communicating with the source eNB by using the relay UE,whether to hand over both the relay UE and the remote user equipmentremote UE to a target eNB. The sending unit is configured to: when it isdetermined to hand over both the relay UE and the remote UE, sendhandover information of the relay UE and handover information of theremote UE to the target eNB, to initiate handover to the target eNB,where the handover information of the relay UE includes a context of therelay UE, and the handover information of the remote UE includes acontext of the remote UE. The receiving unit is configured to receivefirst access information and second access information from the targeteNB, where the first access information is obtained by the target eNBbased on the handover information of the relay UE, so that the relay UEis handed over and accesses the target eNB, and the second accessinformation is obtained by the target eNB based on the handoverinformation of the remote UE, so that the remote UE is handed over andaccesses the target eNB by using the relay UE. The sending unit isconfigured to send the first access information and the second accessinformation to the relay UE, so that the relay UE forwards the secondaccess information to the remote UE. The source eNB receives releaseindication information from the target eNB, where the release indicationinformation is used to instruct the source eNB to release the context ofthe relay UE and the context of the remote UE. The release unit isconfigured to release the context of the relay UE and the context of theremote UE according to the release indication information. Based on asame inventive concept, for a problem-resolving principle and beneficialeffects of the apparatus, refer to the twenty-third aspect, theembodiments of the method of the twenty-third aspect, and the resultingbeneficial effects. Therefore, for implementation of the apparatus,refer to the twenty-third aspect and the embodiments of the method ofthe twenty-third aspect. Details are not described herein again.

According to a twenty-sixth aspect, a target evolved NodeB (eNB) isprovided. The target eNB includes: a receiving unit, an obtaining unit,and a sending unit. The receiving unit is configured to receive handoverinformation of relay user equipment (relay UE) and handover informationof remote user equipment (remote UE) from a source eNB, to determinewhether the relay UE and the remote UE are both allowed to be handedover from the source eNB to the target eNB, where the remote UEcommunicates with the source eNB by using the relay UE, the handoverinformation of the relay UE includes a context of the relay UE, and thehandover information of the remote UE includes a context of the remoteUE. The obtaining unit is configured to: when it is determined that therelay UE and the remote UE are both allowed to be handed over, obtainfirst access information based on the handover information of the relayUE, so that the relay UE is handed over and accesses the target eNB. Theobtaining unit is further configured to obtain second access informationbased on the handover information of the remote UE, so that the remoteUE is handed over and accesses the target eNB by using the relay UE. Thesending unit is configured to send the first access information and thesecond access information to the source eNB, so that the source eNBforwards the first access information to the relay UE and forwards thesecond access information to the remote UE. The receiving unit isfurther configured to receive a handover success indication of the relayUE and a handover success indication of the remote UE, where thehandover success indication of the relay UE is used to indicate that therelay UE is successfully handed over and accesses the target eNB, andthe handover success indication of the remote UE is used to indicatethat the remote UE is successfully handed over and accesses the targeteNB by using the relay UE. The sending unit is further configured tostart path switch procedures for the relay UE and the remote UE. Thesending unit is further configured to send release indicationinformation to the source eNB after it is determined that the relay UEand the remote UE complete the path switch procedures, where the releaseindication information is used to instruct the source eNB to release thecontext of the relay UE and the context of the remote UE. Based on asame inventive concept, for a problem-resolving principle and beneficialeffects of the apparatus, refer to the twenty-fourth aspect, theembodiments of the method of the twenty-fourth aspect, and the resultingbeneficial effects. Therefore, for implementation of the apparatus,refer to the twenty-fourth aspect and the embodiments of the method ofthe twenty-fourth aspect. Details are not described herein again.

According to a twenty-seventh aspect, a source evolved NodeB (eNB) isprovided. The source eNB includes: a processor, a memory, a bus, and acommunications interface. The memory is configured to store a computerexecutable instruction. The processor is connected to the memory via thebus. When the source eNB runs, the processor executes the computerexecutable instruction stored in the memory, so that the source eNBperforms the method according to any one of the twenty-third aspect andthe embodiments of the twenty-third aspect.

According to a twenty-eighth aspect, a target evolved NodeB eNB isprovided. The target eNB includes: a processor, a memory, a bus, and acommunications interface. The memory is configured to store a computerexecutable instruction. The processor is connected to the memory via thebus. When the target eNB runs, the processor executes the computerexecutable instruction stored in the memory, so that the target eNBperforms the method according to any one of the twenty-fourth aspect andthe embodiments of the twenty-fourth aspect.

According to a twenty-ninth aspect, a computer storage medium isprovided. The computer storage medium includes an instruction, and whenthe instruction is run on a computer, the computer is enabled to performthe method according to any one of the twenty-third aspect and theembodiments of the twenty-third aspect.

According to a thirtieth aspect, a computer storage medium is provided.The computer storage medium includes an instruction, and when theinstruction is run on a computer, the computer is enabled to perform themethod according to any one of the twenty-fourth aspect and theembodiments of the twenty-fourth aspect.

According to a thirty-first aspect, a computer program product includingan instruction is provided. When the computer program product is run ona computer, the computer is enabled to perform the method according toany one of the twenty-third aspect and the embodiments of thetwenty-third aspect.

According to a thirty-second aspect, a computer program productincluding an instruction is provided. When the computer program productis run on a computer, the computer is enabled to perform the methodaccording to any one of the twenty-fourth aspect and the embodiments ofthe twenty-fourth aspect.

According to a thirty-third aspect, a communications system is provided.The communications system includes the source evolved NodeB (eNB)according to the twenty-fifth aspect and the target eNB according to thetwenty-sixth aspect, or includes the source eNB according to thetwenty-seventh aspect and the target eNB according to the twenty-eighthaspect.

It should be noted that, for technical effects brought in thetwenty-seventh aspect to the thirty-third aspect, refer to the technicaleffects brought by corresponding methods. Details are not describedherein again.

BRIEF DESCRIPTION OF DRAWINGS

To describe the technical solutions in the embodiments of thisapplication more clearly, the following briefly describes theaccompanying drawings used in conjunction with the detailed descriptionfor describing the embodiments.

FIG. 1 is an overall structural diagram of a communications systemaccording to an embodiment of this application;

FIG. 2 is a structural diagram of hardware of a communications systemaccording to an embodiment of this application;

FIG. 3 is a diagram of a scenario in which remote UE and relay UE areboth handed over according to an embodiment of this application;

FIG. 4 is a flowchart of an S1 handover-based handover method accordingto an embodiment of this application;

FIG. 5A and FIG. 5B are a flowchart of another S1 handover-basedhandover method according to an embodiment of this application;

FIG. 6A and FIG. 6B are a flowchart of still another S1 handover-basedhandover method according to an embodiment of this application;

FIG. 7A and FIG. 7B are a flowchart of an X2 handover-based handovermethod according to an embodiment of this application;

FIG. 8A and FIG. 8B are a flowchart of another X2 handover-basedhandover method according to an embodiment of this application;

FIG. 9A and FIG. 9B are a flowchart of still another X2 handover-basedhandover method according to an embodiment of this application;

FIG. 10 is a flowchart of yet another X2 handover-based handover methodaccording to an embodiment of this application;

FIG. 11 is a flowchart of yet another X2 handover-based handover methodaccording to an embodiment of this application;

FIG. 12 is a structural diagram of an eNB according to an embodiment ofthis application;

FIG. 13 is a structural diagram of another eNB according to anembodiment of this application;

FIG. 14 is a structural diagram of an MME according to an embodiment ofthis application; and

FIG. 15 is a structural diagram of another MME according to anembodiment of this application.

DESCRIPTION OF EMBODIMENTS

The following describes the embodiments of this application withreference to the accompanying drawings.

In addition, this application describes each aspect with reference to awireless network device. The wireless network device may be a basestation. The base station may be configured to communicate with one ormore user equipment, or may be configured to communicate with one ormore base stations having some functions of user equipment (for example,communication between a macro base station and a micro base station suchas an access point). Alternatively, the wireless network device may beuser equipment. The user equipment may be configured to communicate withone or more user equipment (for example, D2D communication), or may beconfigured to communicate with one or more base stations. The userequipment may also be referred to as a user terminal, and may includesome or all functions of a system, a subscriber unit, a subscriberstation, a mobile station, a mobile wireless terminal, a mobile device,a node, a device, a remote station, a remote terminal, a terminal, awireless communications device, a wireless communications apparatus, ora user agent. The user equipment may be a cellular phone, a cordlessphone, a session initiation protocol (SIP) phone, a smartphone, awireless local loop (WLL) station, a personal digital assistant (PDA), alaptop computer, a handheld communications device, a handheld computingdevice, a satellite wireless device, a wireless modem card, and/oranother processing device configured to communicate in a wirelesssystem. The base station may also be referred to as an access point, anode, a NodeB, an evolved NodeB, or another network entity, and mayinclude some or all functions of the foregoing network entities. Thebase station may communicate with a wireless terminal by using an airinterface. The communication may be performed by using one or moresectors. The base station may convert a received air interface frameinto an Internet protocol (IP) packet, to use the IP packet as a routerbetween the wireless terminal and a remaining part of an access network.The access network includes an IP network. The base station may furthercoordinate attribute management of the air interface, and mayalternatively be a gateway between a wired network and a wirelessnetwork.

The network architecture and the service scenario described in theembodiments of this application are intended to describe the technicalsolutions in the embodiments of this application more clearly, and donot constitute a limitation on the technical solutions provided in theembodiments of this application. A person of ordinary skill in the artmay know that: With evolution of the network architecture and emergenceof new service scenarios, the technical solutions provided in theembodiments of this application are also applicable to similar technicalproblems.

The embodiments of this application may be applied to a time divisionduplex (TDD) scenario, and may also be applied to a frequency divisionduplex (FDD) scenario.

An embodiment of this application provides a handover system. Referringto FIG. 1, the handover system includes: remote UE 11, relay UE 12, aneNB 13, a mobility management entity (MME) 14, a home subscriber server(HSS) 15, a serving gateway (S-GW) 16, and a packet data network gateway(P-GW) 17. The MME 14, the HSS 15, the S-GW 16, the P-GW 17, and thelike are core network devices. The remote UE 11 and the relay UE 12 areUEs, and the relay UE 12 communicates with the eNB 13 by using a radiolink. The remote UE 11 does not directly communicate with the eNB 13;but indirectly communicates with the eNB 13 by using the relay UE 12,and further communicates with the core network device.

FIG. 2 is a structural diagram of hardware of devices according to anembodiment of this application. UE 100 includes at least one processor101, at least one memory 102, and at least one transceiver 103.Optionally, the UE 100 may further include an output device 104 and aninput device 105.

The processor 101, the memory 102, and the transceiver 103 are connectedvia a bus. The processor 101 may be a general-purpose central processingunit (CPU), a microprocessor, an application-specific integrated circuit(ASIC)), or one or more integrated circuits configured to controlprogram execution in the solutions of this application. The processor101 may alternatively be a plurality of processors, and each processormay be a single-core (single-CPU) processor or a multi-core (multi-CPU)processor. The processors herein may be one or more devices, circuits,and/or processing cores configured to process data (for example, acomputer program instruction).

The memory 102 may be a read-only memory (ROM) or another type of staticstorage device that may store static information and instructions, arandom access memory (RAM) or another type of dynamic storage devicethat may store information and instructions, or may be an electricallyerasable programmable read-only memory (EEPROM), a compact discread-only memory (CD-ROM) or another compact disc storage, an opticaldisc storage (including a compact optical disc, a laser disc, an opticaldisc, a digital versatile optical disc, a blue optical disc, or thelike), a magnetic disk storage medium or another magnetic storagedevice, or any other medium that can carry or store expected programcode in a form of an instruction or a data structure and can be accessedby a computer. However, this is not limited thereto. The memory 102 mayexist independently, and is connected to the processor 101 via the bus.Alternatively, the memory 102 may be integrated with the processor 101.The memory 102 is configured to store application program code forexecuting the solutions of this application, and the application programcode is executed under control of the processor 101. The processor 101is configured to execute the computer program code stored in the memory102, to implement the method in the embodiments of this application.

The transceiver 103 may use any apparatus of a transceiver type, and isconfigured to communicate with another device or a communicationsnetwork such as the Ethernet, a radio access network (RAN), or awireless local area network (WLAN). The transceiver 103 includes atransmitter Tx and a receiver Rx.

The output device 104 communicates with the processor 101, and maydisplay information in a plurality of manners. For example, the outputdevice 104 may be a liquid crystal display (LCD), a light emitting diode(LED) display device, a cathode ray tube (CRT) display device, or aprojector. The input device 105 communicates with the processor 101, andmay receive user input in a plurality of manners. For example, the inputdevice 105 may be a mouse, a keyboard, a touchscreen device, or asensing device.

An eNB 200 includes at least one processor 201, at least one memory 202,at least one transceiver 203, and at least one network interface 204.The network interface 204 is configured to connect to a networkinterface 303 of a core network device 300 by using a link (for example,an S1 interface), or connect to a network interface 204 of another eNBby using a wired or wireless link (for example, an X2 interface). Forfunctions of the components in the eNB 200, refer to the functiondescriptions of the components in the UE 100. Details are not describedherein again.

The core network device 300 may further provide a network connection,such as a telephone network and/or a data communications network (suchas the Internet). The core network device 300 includes at least oneprocessor 301, at least one memory 302, and at least one networkinterface 303. For functions of the components in the core networkdevice 300, refer to the function descriptions of the components in theUE 100. Details are not described herein again.

A handover method, an apparatus, and a system that are provided in theembodiments of this application are mainly specific to a scenario shownin FIG. 3 in which both remote UE 11 and relay UE 12 are handed overfrom a source eNB 131 to a target eNB 132.

An embodiment of this application provides a handover method, used forS1 handover between eNBs. Referring to FIG. 4, the method includesoperations S101 to S107.

Operation S101. When remote UE communicates with a network side by usingrelay UE, a source eNB serving both the remote UE and the relay UEdetermines, based on a measurement report of the relay UE, to hand overthe relay UE to a target eNB.

The source eNB serving both the remote UE and the relay UE may beunderstood as not only a base station serving the remote UE but also abase station serving the relay UE.

If determining that the relay UE is UE of a relay type, the source eNBperforms handover of the relay type. A difference from common handoverlies in that: The source eNB hands over, to the target eNB, a context ofanother remote UE bound to the relay UE. In this case, the source eNBdetermines to perform S1 interface handover.

When a source MME of the remote UE is the same as a source MME of therelay UE, operation S102 is performed. When there is no need todetermine whether a source MME of the remote UE is the same as a sourceMME of the relay UE, or when a source MME of the remote UE is differentfrom a source MME of the relay UE, operation S103 is performed.

Operation S102. The source eNB sends a first handover required message(handover required) to the source MME of the relay UE, where the firsthandover required message includes identifier information of the relayUE and identifier information of the remote UE, and the first handoverrequired message is used to instruct both the relay UE and the remote UEto the target eNB.

The source MME of the remote UE is an MME currently serving the remoteUE, and the source MME of the relay UE is an MME currently serving therelay UE.

The identifier information of the relay UE or the identifier informationof the remote UE may include at least one of the following: an S1-APidentity, for example, an MME UE S1AP ID and an eNB UE S1AP ID; and anidentifier allocated by the MME, for example, a globally uniquetemporary UE identity (GUTI), a system architecture evolution(SAE)-temporary mobile subscriber identity (S-TMSI), and anMME-temporary mobile subscriber identity (M-TMSI).

There may be a plurality of manners of instructing, by using the firsthandover required message, to hand over both the relay UE and the remoteUE. For example, the first handover required message includes grouphandover indication information, and the group handover indicationinformation is used to instruct to hand over both the relay UE and theremote UE to the target eNB. Alternatively, a message header of thefirst handover required message includes a message type, and the messagetype is used to instruct to hand over both the relay UE and the remoteUE to the target eNB.

In one embodiment, the first handover required message may furtherinclude an association relationship between the relay UE and the remoteUE. In one embodiment, if the source MME stores the associationrelationship between the relay UE and the remote UE, the message doesnot need to carry the association relationship between the relay UE andthe remote UE, or does not need to carry the identifier information ofthe remote UE.

Operation S104 is performed after operation S102.

Operation S103. The source eNB sends a second handover required messageto the source MME of the remote UE, where the second handover requestincludes identifier information of the relay UE, and the second handoverrequired message is used to instruct to hand over the remote UE to thetarget eNB and associate the remote UE with relay UE corresponding to anidentifier of the relay UE; and the source eNB sends a third handoverrequired message to the source MME of the relay UE, where the thirdhandover request includes the identifier information of the relay UE,and the third handover required message is used to instruct to hand overthe relay UE to the target eNB.

An order of sending the second handover required message and the thirdhandover required message is not limited in this embodiment of thisapplication. However, the remote UE can be associated with the relay UEonly after the relay UE is also handed over to the target eNB.

This operation means that if finding that source MMES of some remote UEsare not the source MME of the relay UE, the source eNB separately sendshandover required messages for the remote UEs. Similarly, the secondhandover required message may further include an associationrelationship between the relay UE and the remote UE. In one embodiment,if the source MME stores the association relationship between the relayUE and the remote UE, the message does not need to carry the associationrelationship between the relay UE and the remote UE, or does not need tocarry the identifier information of the relay UE.

Operation S104. The source MME receives the handover required messagefrom the source eNB serving both the relay UE and the remote UE.

If determining, based on the handover required message received from thesource eNB, that the handover is group handover in a relay scenario, thesource MME initiates a group handover procedure for the relay UE and theremote UE associated with the relay UE.

In one embodiment, the source MME may determine, based on the grouphandover indication information in the handover required message, thatthe handover is the group handover in the relay scenario; determine,based on the message type in the message header of the handover requiredmessage, that the handover is the group handover in the relay scenario;or determine, based on that the handover required message carries theidentifier information of the relay UE and/or the associationrelationship between the relay UE and the remote UE, that the handoveris the group handover in the relay scenario.

Operation S105. The source MME sends a mobility management (MM) contextof the remote UE and a mobility management context of the relay UE to atarget MME to which the target eNB belongs, to hand over both the remoteUE and the relay UE to the target eNB.

The source MME described herein may be the MME of both the remote UE andthe relay UE, or may include the MME of the remote UE or the MME of therelay UE. The source MME may hand over both the remote UE and the relayUE. In this case, operation S1051 is performed. Alternatively, thesource MME may separately hand over the remote UE, and then bind theremote UE to the relay UE. In this case, step S1052 is performed.

Specifically, referring to FIG. 5A and FIG. 5B, operation S105 mayinclude operation S1051.

Operation S1051. The source MME sends a first redirection requestmessage to the target MME, where the first redirection request messageincludes the mobility management context of the relay UE and themobility management context of the remote UE, to hand over both theremote UE and the relay UE to the target eNB.

The source MME may send a redirection request message (forwardrelocation request) to the target MME, where the redirection requestmessage includes the mobility management context of the relay UE and themobility management context of the remote UE, to hand over both theremote UE and the relay UE.

Specifically, referring to FIG. 5A and FIG. 5B, operation S105 mayinclude operation S1052.

Operation S1052. A first source MME sends a second redirection requestmessage to the target MME, where the second redirection request messageincludes the mobility management context of the relay UE; and a secondsource MME sends a third redirection request message to the target MME,where the third redirection request message includes the mobilitymanagement context of the remote UE and the identifier information ofthe relay UE, to hand over the remote UE to the target eNB and associatethe remote UE with the relay UE corresponding to the identifier of therelay UE.

The source MME may separately send the mobility management context ofthe remote UE and the identifier information of the relay UE to thetarget MME, to separately hand over the remote UE; and then bind theremote UE to the relay UE. That is, the mobility management context ofthe remote UE and the mobility management context of the relay UE may beseparately carried in two redirection request messages.

The first source MME and the second source MME may be a same MME ordifferent MMES. When the first source MME and the second source MME area same MME, the first source MME and the second source MME are the MMEof both the remote UE and the relay UE. When the first source MME andthe second source MME are different MMES, the first source MME is an MMEto which the relay UE belongs, and the second source MME is an MME towhich the remote UE belongs.

In one embodiment, the second source MME may further obtain secondidentifier information of the relay UE in the third redirection requestmessage based on first identifier information of the relay UE in thehandover required message.

Operation S106. The target MME receives the redirection request messagefrom the source MME.

Operation S107. The target MME sends information about the remote UE andinformation about the relay UE to the target eNB, to instruct to handover both the relay UE and the remote UE to the target eNB and enablethe target eNB to associate the remote UE with the relay UE.

The information about the remote UE or the information about the relayUE includes: EPS bearers to setup, aggregate maximum bit rate (AMBR),source to target transparent container, handover restriction list, andthe like.

The target MME described herein may be an MME of both the remote UE andthe relay UE, or may include an MME of the remote UE or an MME of therelay UE. Similarly, the target MME may hand over both the remote UE andthe relay UE. In this case, operation S1071 is performed. Alternatively,the target MME may separately hand over the remote UE, and then bind theremote UE to the relay UE. In this case, operation S1072 is performed.

Specifically, referring to FIG. 5A and FIG. 5B, operation S107 mayinclude operation S1071.

Operation S1071. The target MME sends a first handover request messageto the target eNB, where the first handover request message includes theinformation about the remote UE and the information about the relay UE,and the first handover request message is used to instruct to hand overboth the relay UE and the remote UE to the target eNB and enable thetarget eNB to associate the remote UE with the relay UE.

Specifically, referring to FIG. 5A and FIG. 5B, operation S107 mayinclude step S1072.

Operation S1072. A first target MME sends a second handover requestmessage to the target eNB, where the second handover request messageincludes the information about the relay UE; and a second target MMEsends a third handover request message to the target eNB, where thethird handover request message includes the information about the remoteUE and the identifier information of the relay UE, the third handoverrequest message is used to instruct to hand over the remote UE to thetarget eNB and associate the remote UE with the relay UE correspondingto the identifier information of the relay UE, and the first target MMEand the second target MME may be a same MME or different MMES.

According to the handover method provided in this embodiment of thisapplication, the remote UE communicates with the network side by usingthe relay UE, the source eNB serving both the remote UE and the relay UEdetermines, based on the measurement report of the relay UE, to handover the relay UE to the target eNB, and also needs to hand over theremote UE to the target eNB. In one embodiment, when the source MME ofthe remote UE is the same as the source MME of the relay UE, the sourceeNB sends the first handover required message to the source MME of therelay UE, where the first handover required message includes theidentifier information of the relay UE and the identifier information ofthe remote UE, to instruct to hand over both the relay UE and the remoteUE to the target eNB; or when the source MME of the remote UE isdifferent from the source MME of the relay UE, the source eNB sends thesecond handover required message to the source MME of the remote UE,where the second handover request includes the identifier information ofthe relay UE, so that the remote UE is, after handed over to the targeteNB, associated with the relay UE corresponding to the identifier of therelay UE. In one embodiment, there is no need to determine whether thesource MMES are the same. The source eNB sends the first handoverrequired message to the source MME of the relay UE, where the firsthandover required message is used to instruct to hand over the relay UEto the target eNB; and the source eNB sends the second handover requiredmessage to the source MME of the remote UE, where the second handoverrequest includes the identifier information of the relay UE, and thesecond handover required message is used to instruct to hand over theremote UE to the target eNB and associate the remote UE with the relayUE corresponding to the identifier of the relay UE. In one embodiment,the source MME sends the mobility management context of the remote UEand the mobility management context of the relay UE to the target MME towhich the target eNB belongs, to hand over both the remote UE and therelay UE to the target eNB. In one embodiment, the source MME sends theredirection request message to the target MME to which the target eNBbelongs, where the redirection request message includes the mobilitymanagement context of the remote UE and the identifier information ofthe relay UE, to hand over the remote UE to the target eNB and associatethe remote UE with the relay UE. In one embodiment, the target MME sendsthe information about the remote UE and the information about the relayUE to the target eNB, to instruct to hand over both the relay UE and theremote UE to the target eNB and enable the target eNB to associate theremote UE with the relay UE. In one embodiment, the target MME sends thehandover request message to the target eNB, where the handover requestmessage includes the information about the remote UE and the identifierinformation of the relay UE, and the handover request message is used toinstruct to hand over the remote UE to the target eNB and associate theremote UE with the relay UE corresponding to the identifier informationof the relay UE. S1 handover of both the remote UE and the relay UEbetween the eNBs is implemented by using the foregoing communicationprocesses.

An embodiment of this application provides another handover method, usedfor S1 handover between eNBs. Referring to FIG. 6A and FIG. 6B, themethod includes operations S201 to S224.

Operation S201. When remote UE communicates with a network side by usingrelay UE, a source eNB serving both the remote UE and the relay UEdetermines, based on a measurement report of the relay UE, to hand overthe relay UE to a target eNB.

This operation is the same as operation S101, and details are notdescribed herein again.

Operation S202. When a source MME of the remote UE is the same as asource MME of the relay UE, the source eNB sends a first handoverrequired message to the source MME of the relay UE.

This operation is the same as operation S102, and details are notdescribed herein again.

Operation S203. The source MME receives the first handover requiredmessage.

This operation is the same as operation S104, and details are notdescribed herein again.

Operation S204. The source MME sends a redirection request message to atarget MME, where the redirection request message includes a mobilitymanagement context of the relay UE and a mobility management context ofthe remote UE.

This operation is the same as operation S1051, and details are notdescribed herein again.

Operation S205. After receiving the redirection request message from thesource MME, the target MME sends a handover request message (handoverrequest) to the target eNB, where the handover request message includesfirst information of the remote UE and first information of the relayUE.

This operation is the same as operation S1071, and details are notdescribed herein again.

Operation S206. The target eNB receives the handover request messagefrom the target MME.

Operation S207. The target eNB sends a handover request acknowledgmentmessage to the target MME, where the handover request acknowledgmentmessage includes second information of the relay UE and secondinformation of the remote UE.

The second information includes: EPS bearer setup list, EPS bearersfailed to setup list, source to target transparent container, and thelike.

Operation S208. The target MME receives the handover requestacknowledgment message.

Operation S209. The target MME sends a redirection response message(forward relocation response) to the source MME, where the redirectionresponse message includes third information of the relay UE and thirdinformation of the remote UE.

The third information includes: target to source transparent container,serving gateway change indication, EPS bearer setup list, servinggateway address and tunnel endpoint identifiers for indirect forwarding(Serving GW Address and TEIDs for indirect forwarding), and the like.

Operation S210. The source MME receives the redirection responsemessage.

Operation S211. The source MME sends a handover command message(handover command) to the source eNB, where the handover command messageincludes fourth information of the relay UE and fourth information ofthe remote UE.

The fourth information includes: the target to source transparentcontainer, bearers subject to forwarding, bearers to release, and thelike.

Operation S212. The source eNB receives the handover command message.

Operation S213. The source eNB forwards the handover command message tothe relay UE.

The handover command message includes the target to source transparentcontainer.

Operation S214. The source eNB forwards the handover command message tothe remote UE by using the relay UE.

The handover command message includes the target to source transparentcontainer.

Operation S215. The relay UE sends a handover confirm message to thetarget eNB.

Operation S216. The remote UE sends a handover confirm message to thetarget eNB by using the relay UE.

Operation S217. The target eNB sends a handover notification message tothe target MME.

Operation S218. The target MME receives the handover notificationmessage.

Operation S219. The target MME sends a redirection complete notificationmessage (forward relocation complete notification) to the source MME.

Operation S220. The source MME receives the redirection completenotification message.

Operation S221. The source MME sends a redirection completeacknowledgment message (forward relocation complete acknowledge) to thetarget MME.

Operation S222: The target MME and an SGW complete a modify bearerrequest/response exchange procedure, to complete modifying bearers ofthe relay UE and the remote UE associated with the relay UE.

Operation S223. The source MME sends a UE context release message to thesource eNB.

The UE context release message includes group handover indicationinformation, and in one embodiment, may further include an identifier ofthe relay UE and/or identifiers of all remote UEs associated with therelay UE.

Operation S224. The source eNB releases a context of the relay UE and acontext of the remote UE based on the UE context release message.

According to the handover method provided in this embodiment of thisapplication, the remote UE and the relay UE are both handed over in awearable scenario based on S1 handover between the MMES.

An embodiment of this application provides a handover method, used forX2 handover between eNBs. Referring to FIG. 7A and FIG. 7B, the methodincludes operations S301 to S316.

Operation S301. A source eNB determines, based on a measurement reportof relay UE and depending on whether there is remote UE communicatingwith the source eNB by using the relay UE, whether to hand over both therelay UE and the remote UE to a target eNB.

The source eNB directly communicates with the relay UE, and can obtainthe measurement report of the relay UE. When the relay UE is UE of arelay type (to be specific, there is the remote UE communicating withthe source eNB by using the relay UE), the source eNB may determine,based on the measurement report and depending on whether there is theremote UE communicating with the source eNB by using the relay UE,whether to hand over both the relay UE and the remote UE to the targeteNB. A specific handover reason may be low quality or a low receivelevel. Details are not described in this application.

Operation S302. When determining to hand over both the relay UE and theremote UE to the target eNB, the source eNB sends handover informationof the relay UE and handover information of the remote UE to the targeteNB, to initiate handover to the target eNB, where the handoverinformation of the relay UE includes a context of the relay UE, and thehandover information of the remote UE includes a context of the remoteUE.

A difference from common handover (i.e., there is no remote UEcommunicating with the source eNB by using the relay UE) is that, boththe context of the relay UE and the context of the remote UE need to behanded over to the target eNB.

The handover information is basic information that is ofto-be-handed-over UE and that is necessary for a handover procedure whenthe source eNB initiates the handover to the target eNB. For example,the handover information of the relay UE may include: the context of therelay UE, an identifier of the relay UE, and an association relationshipbetween the relay UE and the remote UE. The identifier of the relay UEor the association relationship between the relay UE and the remote UEmay alternatively be a part of the context of the relay UE. Similarly,the handover information of the remote UE may include: the context ofthe remote UE, an identifier of the remote UE, and the associationrelationship between the relay UE and the remote UE. The identifier ofthe remote UE or the association relationship between the relay UE andthe remote UE may alternatively be a part of the context of the remoteUE.

In addition, when sending the handover information of the relay UE andthe handover information of the remote UE to the target eNB by using aspecific message, the source eNB may further add handover typeindication information to the message, where the handover typeindication information is used to indicate whether a requested handovertype is group handover (that is, handover of both the relay UE and theremote UE) or common handover. It should be noted that a manner ofcarrying the handover type indication information is not limited in thisembodiment of this application. For example, the handover typeindication information may be carried in a newly added informationelement in the message, or may be directly carried in a message typeinformation element in an original message header.

Specifically, the source eNB may send the handover information of therelay UE and the handover information of the remote UE to the target eNBby using a handover request message.

For the handover type indication information, an indication informationinformation-element may be newly added to the handover request message.The indication information information-element is used to instruct tohand over both the relay UE and the remote UE. Alternatively, a messagetype in a message header of the handover request message is directlyused to instruct to hand over both the relay UE and the remote UE.

Operation S303. The target eNB receives the handover information of therelay UE and the handover information of the remote UE from the sourceeNB, to determine whether the relay UE and the remote UE are bothallowed to be handed over from the source eNB to the target eNB.

Operation S304. When determining that the relay UE and the remote UE areboth allowed to be handed over, the target eNB obtains first accessinformation based on the handover information of the relay UE, so thatthe relay UE is handed over and accesses the target eNB; and obtainssecond access information based on the handover information of theremote UE, so that the remote UE is handed over and accesses the targeteNB by using the relay UE.

The first access information may include a new cell radio networktemporary identifier (C-RNTI) allocated to the relay UE, a securityalgorithm identifier selected by the target eNB, and the like.Similarly, the second access information may include a new C-RNTIallocated to the remote UE, a security algorithm identifier selected bythe target eNB, and the like.

Operation S305. The target eNB sends the first access information andthe second access information to the source eNB, so that the source eNBforwards the first access information to the relay UE, and forwards thesecond access information to the remote UE.

Specifically, the target eNB may send the first access information andthe second access information to the source eNB by using a handoverrequest acknowledgment message.

Operation S306. The source eNB receives the first access information andthe second access information from the target eNB.

Operation S307. The source eNB sends the first access information andthe second access information to the relay UE, so that the relay UEforwards the second access information to the remote UE.

Specifically, the source eNB may send the first access information andthe second access information to the relay UE by using a radio resourcecontrol (RRC) connection reconfiguration message.

Operation S308. The relay UE receives the first access information andthe second access information from the source eNB.

Operation S309. The relay UE forwards the second access information tothe remote UE.

Operation S310. The remote UE sends a handover success indication of theremote UE to the relay UE, where the handover success indication of theremote UE is used to indicate that the remote UE is successfully handedover and accesses the target eNB by using the relay UE.

Operation S311. The relay UE sends a handover success indication of therelay UE and the handover success indication of the remote UE to thetarget eNB, where the handover success indication of the relay UE isused to indicate that the relay UE is successfully handed over andaccesses the target eNB.

Specifically, the relay UE may send the handover success indication ofthe relay UE and the handover success indication of the remote UE to thetarget eNB by using an RRC connection reconfiguration complete message.

Operation S312. The target eNB receives the handover success indicationof the relay UE and the handover success indication of the remote UEfrom the relay UE.

Operation S313. The target eNB separately initiates path switchprocedures for the relay UE and the remote UE.

Operation S314. After determining that the relay UE and the remote UEcomplete the path switch procedures, the target eNB sends releaseindication information to the source eNB, where the release indicationinformation is used to instruct the source eNB to release the context ofthe relay UE and the context of the remote UE.

Specifically, the target eNB may send the release indication informationto the source eNB by using a UE context release message. In oneembodiment, the release indication information may include theidentifier of the relay UE, and may further include the identifier ofthe remote UE.

Operation S315. The source eNB receives the release indicationinformation from the target eNB.

Operation S316. The source eNB releases the context of the relay UE andthe context of the remote UE according to the release indicationmessage.

Specifically, when the release indication information includes theidentifier of the relay UE, operation S316 may specifically include:releasing, by the source eNB, the context of the relay UE based on theidentifier of the relay UE; obtaining the identifier of the remote UEbased on the identifier of the relay UE and the association relationshipbetween the relay UE and the remote UE; and then releasing the contextof the remote UE based on the identifier of the remote UE.

When the release indication information includes the identifier of therelay UE and the identifier of the remote UE, step S316 may specificallyinclude: releasing, by the source eNB, the context of the relay UE basedon the identifier of the relay UE; and releasing the context of theremote UE based on the identifier of the remote UE.

According to the handover method provided in this embodiment of thisapplication, when the source eNB initiates to hand over both the remoteUE and the relay UE to the target eNB, the handover information of theremote UE and the handover information of the relay UE are carried, andinclude the context of the remote UE and the context of the relay UE.The target eNB obtains the access information of the remote UE and theaccess information of the relay UE based on the handover information ofthe remote UE and the handover information of the relay UE, and thesource eNB forwards the access information to the remote UE and therelay UE, so that the remote UE and the relay UE access a target eNBbased on respective access information. After the remote UE and therelay UE are successfully handed over and access the target eNB, thetarget eNB instructs the source eNB to release the context of the remoteUE and the context of the relay UE. The context of the remote UE and thecontext of the relay UE are transferred from the source eNB to thetarget eNB, and the remote UE and the relay UE successfully access thetarget eNB. Therefore, the remote UE and the relay UE are both handedover in a wearable scenario.

The following further extends the foregoing handover method withreference to FIG. 8A and FIG. 8B, and FIG. 9A and FIG. 9B.

For operation S302:

In one embodiment, one handover request message may carry the handoverinformation of the relay UE and the handover information of the remoteUE. Referring to FIG. 8A and FIG. 8B, operation S302 may includeoperation S3021.

Operation S3021. The source eNB sends a first handover request messageto the target eNB, where the first handover request message includes thehandover information of the relay UE and the handover information of theremote UE.

In one embodiment, one of two handover request messages may carry thehandover information of the relay UE, and the other handover requestmessage may carry the handover information of the remote UE. Further, anorder of sending the two handover request messages is not limited. To bespecific, the handover information of the relay UE may be first sent, orthe handover information of the remote UE may be first sent. Referringto FIG. 9A and FIG. 9B, operation S302 may include operations S3022 andS3023.

Operation S3022. The source eNB sends a second handover request messageto the target eNB, where the second handover request message includesthe handover information of the relay UE.

Operation S3023. The source eNB sends a third handover request messageto the target eNB, where the third handover request message includes thehandover information of the remote UE.

Correspondingly, for operation S303:

In one embodiment, referring to FIG. 8A and FIG. 8B, operation S303 mayinclude operation S3031.

Operation S3031. The target eNB receives the first handover requestmessage from the source eNB, where the first handover request messageincludes the handover information of the relay UE and the handoverinformation of the remote UE.

In one embodiment, referring to FIG. 9A and FIG. 9B, operation S303 mayinclude operations S3032 and S3033.

Operation S3032. The target eNB receives the second handover requestmessage from the source eNB, where the second handover request messageincludes the handover information of the relay UE.

Operation S3033. The target eNB receives the third handover requestmessage from the source eNB, where the third handover request messageincludes the handover information of the remote UE.

For operation S305:

In one embodiment, one handover request acknowledgment message may carrythe first access information and the second access information.Referring to FIG. 8A and FIG. 8B, operation S305 may include operationS3051.

Operation S3051. The target eNB sends a first handover requestacknowledgment message to the source eNB, where the first handoverrequest acknowledgment message includes the first access information andthe second access information.

In one embodiment, one of two handover request acknowledgment messagesmay carry the first access information, and the other handover requestacknowledgment message may carry the second access information. Further,an order of sending the two handover request acknowledgment messages isnot limited. To be specific, the first access information may be firstsent, or the second access information may be first sent. Referring toFIG. 9A and FIG. 9B, operation S305 may include operations S3052 andS3053.

Operation S3052. The target eNB sends a second handover requestacknowledgment message to the source eNB, where the second handoverrequest acknowledgment message includes the first access information.

Operation S3053. The target eNB sends a third handover requestacknowledgment message to the source eNB, where the third handoverrequest acknowledgment message includes the second access information.

Correspondingly, for operation S306:

In one embodiment, referring to FIG. 8A and FIG. 8B, operation S306 mayinclude operation S3061.

Operation S3061. The source eNB receives the first handover requestacknowledgment message from the target eNB, where the first handoverrequest acknowledgment message includes the first access information andthe second access information.

In one embodiment, referring to FIG. 9A and FIG. 9B, operation S306 mayinclude operations S3062 and S3063.

Operation S3062. The source eNB receives the second handover requestacknowledgment message from the target eNB, where the second handoverrequest acknowledgment message includes the first access information.

Operation S3063. The source eNB receives the third handover requestacknowledgment message from the target eNB, where the third handoverrequest acknowledgment message includes the second access information.

For operation S307:

In one embodiment, one RRC connection reconfiguration message may carrythe first access information and the second access information. Therelay UE obtains the second access information through parsing and thenforwards the second access information to the remote UE. Referring toFIG. 8A and FIG. 8B, operation S307 may include operation S3071.

Operation S3071. The source eNB sends a first RRC connectionreconfiguration message to the relay UE, so that the relay UE forwardsthe second access information to the remote UE, where the first RRCconnection reconfiguration message includes the first access informationand the second access information.

In one embodiment, one of two RRC connection reconfiguration messagesmay carry the first access information, and the other RRC connectionreconfiguration message may carry the second access information and isdirectly transparently transmitted by the relay UE to the remote UE.Further, an order of sending the two RRC connection reconfigurationmessages is not limited. To be specific, the first access informationmay be first sent, or the second access information may be first sent.Referring to FIG. 9A and FIG. 9B, operation S307 may include operationsS3072 and S3073.

Operation S3072. The source eNB sends a second RRC connectionreconfiguration message to the relay UE, where the second RRC connectionreconfiguration message includes the first access information.

Operation S3073. The source eNB sends a third RRC connectionreconfiguration message to the relay UE, so that the relay UE forwardsthe second access information to the remote UE, where the third RRCconnection reconfiguration message includes the second accessinformation.

Correspondingly, for operation S308:

In one embodiment, referring to FIG. 8A and FIG. 8B, operation S308 mayinclude operation S3081.

Operation S3081. The relay UE receives the first RRC connectionreconfiguration message from the source eNB, where the first RRCconnection reconfiguration message includes the first access informationand the second access information.

In one embodiment, referring to FIG. 9A and FIG. 9B, operation S308 mayinclude operations S3082 and S3083.

Operation S3082. The relay UE receives the second RRC connectionreconfiguration message from the source eNB, where the second RRCconnection reconfiguration message includes the first accessinformation.

Operation S3083. The relay UE receives the third RRC connectionreconfiguration message from the source eNB, where the third RRCconnection reconfiguration message includes the second accessinformation.

Correspondingly, for operation S309:

In one embodiment, referring to FIG. 8A and FIG. 8B, operation S309 mayinclude operation S3091.

Operation S3091. The relay UE parses the first RRC connectionreconfiguration message to obtain the second access information, andforwards the second access information to the remote UE.

In this embodiment of this application, a message used by the relay UEto forward the second access information to the remote UE is notlimited. For example, an RRC message used for D2D communication may beused, or the RRC connection reconfiguration message may bereconstructed.

In one embodiment, referring to FIG. 9A and FIG. 9B, operation S309 mayinclude operation S3092.

Operation S3092. The relay UE forwards the third RRC connectionreconfiguration message to the remote UE.

In this case, the relay UE only acts as a relay for transparenttransmission of the message.

For operation S311:

In one embodiment, one RRC connection reconfiguration complete messagemay carry the handover success indication of the relay UE and thehandover success indication of the remote UE. Referring to FIG. 8A andFIG. 8B, operation S311 may include operation S3111.

Operation S3111. The relay UE sends a first RRC connectionreconfiguration complete message to the target eNB, where the first RRCconnection reconfiguration complete message includes the handoversuccess indication of the relay UE and the handover success indicationof the remote UE.

In one embodiment, one of two RRC connection reconfiguration completemessages may carry the handover success indication of the relay UE, andthe other RRC connection reconfiguration complete message may carry thehandover success indication of the remote UE. Further, an order ofsending the two RRC connection reconfiguration complete messages is notlimited. To be specific, the handover success indication of the relay UEmay be first sent, or the handover success indication of the remote UEmay be first sent. Referring to FIG. 9A and FIG. 9B, operation S311 mayinclude operations S3112 and S3113.

Operation S3112. The relay UE sends a second RRC connectionreconfiguration complete message to the target eNB, where the second RRCconnection reconfiguration complete message includes the handoversuccess indication of the relay UE.

Operation S3113. The relay UE sends a third RRC connectionreconfiguration complete message to the target eNB, where the third RRCconnection reconfiguration complete message includes the handoversuccess indication of the remote UE.

Correspondingly, for operation S312:

Optionally, referring to FIG. 8A and FIG. 8B, step S312 may includeoperation S3121.

Operation S3121. The target eNB receives the first RRC connectionreconfiguration complete message from the relay UE, where the first RRCconnection reconfiguration complete message includes the handoversuccess indication of the relay UE and the handover success indicationof the remote UE.

In one embodiment, referring to FIG. 9A and FIG. 9B, operation S312 mayinclude operations S3122 and S3123.

Operation S3122. The target eNB receives the second RRC connectionreconfiguration complete message from the relay UE, where the second RRCconnection reconfiguration complete message includes the handoversuccess indication of the relay UE.

Operation S3123. The target eNB receives the third RRC connectionreconfiguration complete message from the relay UE, where the third RRCconnection reconfiguration complete message includes the handoversuccess indication of the remote UE.

Although the handover method is described by using only two flowcharts,namely, FIG. 8A and FIG. 8B, and FIG. 9A and FIG. 9B, in this embodimentof this application, a person skilled in the art may understand that:First, a chronological order of performing the foregoing operations isnot limited in this application. For example, operation S3023 may befirst performed, and then step S3022 is performed; and operation S3033is first performed, and then operation S3032 is performed. Details arenot described. Second, in the handover procedure in FIG. 8A and FIG. 8Bor FIG. 9A and FIG. 9B, whether information is transmitted by using twomessages or one message is not limited. For example, in a handoverprocedure, the source eNB may perform operation S3021 when sending thehandover request message to the target eNB; and the target eNB mayperform operations S3052 and S3053 when feeding back the handoverrequest acknowledgment message to the source eNB. Details are notdescribed.

For operation S313, in one embodiment, referring to FIG. 10, operationS313 may include the following operations.

Operation S401. The target eNB sends a first path switch request messageto an MME to which the relay UE belongs, where the first path switchrequest message includes the identifier of the relay UE.

The first path switch request message is used to notify the MME to whichthe relay UE belongs that an access cell of the relay UE has changed,and request to update a node address of a service data channel.

Operation S402. The MME to which the relay UE belongs sends a firstmodify bearer request message to an S-GW.

Operation S403. The S-GW sends a first modify bearer response message tothe MME to which the relay UE belongs.

Operation S404. The MME to which the relay UE belongs sends a first pathswitch response message to the target eNB.

The first path switch response message indicates that the relay UE mayperform service communication on a new system architecture evolution(SAE) bearer.

Operation S405. The target eNB sends a second path switch requestmessage to an MME to which the remote UE belongs, where the second pathswitch request message includes the identifier of the remote UE.

The second path switch request message is used to notify the MME towhich the remote UE belongs that an access cell of the remote UE haschanged, and request to update a node address of a service data channel.

Operation S406. The MME to which the remote UE belongs sends a secondmodify bearer request message to an S-GW.

Operation S407. The S-GW sends a second modify bearer response messageto the MME to which the remote UE belongs.

Operation S408. The MME to which the remote UE belongs sends a secondpath switch response message to the target eNB.

The second path switch response message indicates that the remote UE mayperform service communication on a new SAE bearer.

In one embodiment, referring to FIG. 11, operation S313 may include thefollowing operations.

Operation S501. The target eNB sends a third path switch request messageto an MME to which the relay UE belongs, where the third path switchrequest message includes the identifier of the relay UE and theidentifier of the remote UE.

The third path switch request message is used to notify the MME to whichthe relay UE belongs that an access cell of the relay UE has changed,and request to update a node address of a service data channel.

Operation S502. The MME to which the relay UE belongs sends a thirdmodify bearer request message to the S-GW.

Operation S503. The S-GW sends a third modify bearer response message tothe MME to which the relay UE belongs.

Operation S504. The MME to which the relay UE belongs sends a forwardingpath switch request message to an MME to which the remote UE belongs,where the forwarding path switch request message includes the identifierof the remote UE.

Operation S505. The MME to which the remote UE belongs sends a fourthmodify bearer request message to an S-GW.

Operation S506. The S-GW sends a fourth modify bearer response messageto the MME to which the remote UE belongs.

Operation S507. The MME to which the remote UE belongs sends aforwarding path switch response message to the MME to which the relay UEbelongs.

Operation S508. The MME to which the relay UE belongs sends a third pathswitch response message to the target eNB.

Compared with the path switch procedure in FIG. 10, in the path switchprocedure in FIG. 11, when the MME to which the relay UE belongs and theMME to which the remote UE belongs are a same MME, operations S504 andS507 may be omitted, so that a signaling procedure is reduced, and aresponse speed is higher.

An embodiment of this application provides an eNB, configured to performthe foregoing method. In this embodiment of this application, the eNBmay be divided into function modules based on the foregoing methodexamples. For example, function modules corresponding to functions maybe obtained through division, or two or more functions may be integratedinto one processing module. The integrated module may be implemented ina form of hardware, or may be implemented in a form of a softwarefunction module. It should be noted that, in this embodiment of thisapplication, module division is used as an example, and is merelylogical function division. In an actual implementation, another divisionmay be used.

When the function modules corresponding to the functions are obtainedthrough division, FIG. 12 is a possible structural diagram of the eNB inthe foregoing embodiments. An eNB 40 includes: a receiving unit 4011, adetermining unit 4012, a sending unit 4013, a release unit 4014, and anobtaining unit 4015. The receiving unit 4011 is configured to supportthe eNB 40 in performing the process S212 in FIG. 6A and FIG. 6B, theprocesses S303, S306, S312, and S315 in FIG. 7A and FIG. 7B, theprocesses S3031, S3061, and S3121 in FIG. 8A and FIG. 8B, and theprocesses S3032, S3033, S3062, S3063, S3122, and S3123 in FIG. 9A andFIG. 9B. The determining unit 4012 is configured to support the eNB 40in performing the process S101 in FIG. 4, the processes S201 and S206 inFIG. 6A and FIG. 6B, and the processes S301 and S315 in FIG. 7A and FIG.7B. The sending unit 4013 is configured to support the eNB 40 inperforming the processes S102 and S103 in FIG. 4, the processes S202,S207, S213, S214, and S217 in FIG. 6A and FIG. 6B, the processes S302,S305, S307, S313, and S314 in FIG. 7A and FIG. 7B, the processes S3021,S3051, and S3071 in FIG. 8A and FIG. 8B, the processes S3022, S3023,S3052, S3053, S3072, and S3073 in FIG. 9A and FIG. 9B, the processesS401 and S405 in FIG. 10, and the process S501 in FIG. 11. The releaseunit 4014 is configured to support the eNB 40 in performing the processS224 in FIG. 6A and FIG. 6B and the process S316 in FIG. 7A and FIG. 7B.The obtaining unit 4015 is configured to support the eNB 40 inperforming the process S304 in FIG. 7A and FIG. 7B. All related contentof operations in the foregoing method embodiments may be cited infunction descriptions of corresponding function modules, and details arenot described herein again.

When the integrated unit is used, FIG. 13 is a possible structuraldiagram of the eNB in the foregoing embodiments. An eNB 40 includes aprocessing module 4022 and a communications module 4023. The processingmodule 4022 is configured to control and manage actions of the eNB 40.For example, the processing module 4022 is configured to support the eNB40 in performing the process S101 in FIG. 4, the processes S201 and S206in FIG. 6A and FIG. 6B, the processes S301 and S315 in FIG. 7A and FIG.7B, the process S224 in FIG. 6A and FIG. 6B, the process S316 in FIG. 7Aand FIG. 7B, and the process S304 in FIG. 7A and FIG. 7B. Thecommunications module 4023 is configured to support communicationbetween the eNB and another entity, for example, communication with afunction module or a network entity shown in FIG. 1. The eNB 40 mayfurther include a storage module 4021, configured to store program codeand data of the eNB.

The processing module 4022 may be the processor 201 in FIG. 2. Thecommunications module 4023 may be the transceiver 203 and the networkinterface 204 in FIG. 2. The storage module 4021 may be the memory 202in FIG. 2.

An embodiment of this application provides an MME, configured to performthe foregoing method. In this embodiment of this application, the MMEmay be divided into function modules based on the foregoing methodexamples. For example, function modules corresponding to functions maybe obtained through division, or two or more functions may be integratedinto one processing module. The integrated module may be implemented ina form of hardware, or may be implemented in a form of a softwarefunction module. It should be noted that, in this embodiment of thisapplication, module division is used as an example, and is merelylogical function division. In an actual implementation, another divisionmay be used.

When the function modules corresponding to functions are obtainedthrough division, FIG. 14 is a possible structural diagram of the MME inthe foregoing embodiments. An MME 50 includes: a receiving unit 5011, anobtaining unit 5012, and a sending unit 5013. The receiving unit 5011 isconfigured to support the MME 50 in performing the processes S104 andS106 in FIG. 4, and the processes S203, S208, S210, S218, and S220 inFIG. 6A and FIG. 6B. The obtaining unit 5012 is configured to supportthe MME 50 in performing the process S1052 in FIG. 5A and FIG. 5B. Thesending unit 5013 is configured to support the MME 50 in performing theprocesses S105 and S107 in FIG. 4, the processes S1051, 1052, S1071, andS1072 in FIG. 5A and FIG. 5B, the processes S204, S205, S209, S211,S219, S221, and S223 in FIG. 6A and FIG. 6B, the processes S402, S404,S406, and S408 in FIG. 10, and the processes S502, S504, S505, S507, andS508 in FIG. 11. All related content of operations in the foregoingmethod embodiments may be cited in function descriptions ofcorresponding function modules, and details are not described hereinagain.

When the integrated unit is used, FIG. 15 is a possible structuraldiagram of the MME in the foregoing embodiments. An MME 50 includes aprocessing module 5022 and a communications module 5023. The processingmodule 5022 is configured to control and manage actions of the MME 50.For example, the processing module 5022 is configured to support the MME50 in performing the process S1052 in FIG. 5A and FIG. 5B. Thecommunications module 5023 is configured to support communicationbetween the MME and another entity, for example, communication with afunction module or a network entity shown in FIG. 1. The MME 50 mayfurther include a storage module 5021, configured to store program codeand data of the MME.

The processing module 5022 may be the processor 301 in FIG. 2. Thecommunications module 5023 may be the network interface 303 in FIG. 2.The storage module 5021 may be the memory 302 in FIG. 2. The methods inthe embodiments may be applied to the processor, and the processor maybe an integrated circuit chip.

The foregoing descriptions are merely specific implementations of thisapplication, but are not intended to limit the protection scope of thisapplication. Any variation or replacement readily figured out by aperson skilled in the art within the technical scope disclosed in thisapplication shall fall within the protection scope of this application.Therefore, the protection scope of this application shall be subject tothe protection scope of the claims.

What is claimed is:
 1. A handover method for a relay user equipment (UE)and a remote UE that communicates with a network through the relay UE,comprising: determining, by a source evolved NodeB (eNB) of the networkserving both the remote UE and the relay UE, based on a measurementreport of the relay UE, to handover the relay UE to a target eNB; andsending, by the source eNB, a first handover required message to asource mobility management entity (MME) of the relay UE when a sourceMME of the remote UE is the same as the source MME of the relay UE,wherein the first handover required message comprises identifierinformation of the relay UE, and the first handover required message isused to instruct a handover of both the relay UE and the remote UE tothe target eNB; or sending, by the source eNB, a second handoverrequired message to the source MME of the remote UE and a third handoverrequired message to the source MME of the relay UE when the source MMEof the remote UE is different from the source MME of the relay UE,wherein the second handover required message comprises identifierinformation of the relay UE, and the second handover required message isused to instruct a handover of the remote UE to the target eNB and anassociation of the remote UE with the relay UE, and wherein the thirdhandover required message comprises the identifier information of therelay UE, and the third handover required message is used to instruct ahandover of the relay UE to the target eNB.
 2. The handover methodaccording to claim 1, wherein the first handover required messagecomprises: group handover indication information, and wherein the grouphandover indication information is used to instruct the handover of boththe relay UE and the remote UE to the target eNB; or a message headerthat comprises a message type, and wherein the message type is used toinstruct the handover of both the relay UE and the remote UE to thetarget eNB.
 3. The handover method according to claim 1, wherein theidentifier information of the relay UE comprises at least one of thefollowing: a globally unique temporary identity (GUTI), a systemarchitecture evolution (SAE)-temporary mobile subscriber identity(S-TMSI), an MME-temporary mobile subscriber identity (M-TMSI), or a UES1 application protocol (S1-AP) identity.
 4. The handover methodaccording to claim 1, wherein the first handover required messagecomprises: an association relationship between the relay UE and theremote UE.
 5. The handover method according to claim 1, wherein thefirst handover required message comprises: identifier information of theremote UE.
 6. A handover method for a relay user equipment (UE) and aremote UE that communicates with a network through the relay UE,comprising: determining, by a source evolved NodeB (eNB) of the networkserving both the remote UE and the relay UE, based on a measurementreport of the relay user equipment (UE), to handover the relay UE to atarget eNB; sending, by the source eNB, a first handover requiredmessage to a source mobility management entity (MME) of the relay UE,wherein the first handover required message is used to instruct ahandover of the relay UE to the target eNB; and sending, by the sourceeNB, a second handover required message to a source MME of the remoteUE, wherein the second handover required message comprises identifierinformation of the relay UE, and the second handover required message isused to instruct a handover of the remote UE to the target eNB and anassociation of the remote UE with the relay UE corresponding to theidentifier information of the relay UE.
 7. The handover method accordingto claim 6, wherein the identifier information of the relay UE comprisesat least one of the following: a globally unique temporary UE identityGUTI, a system architecture evolution (SAE)-temporary mobile subscriberidentity (S-TMSI), an MME-temporary mobile subscriber identity (M-TMSI),or a UE S1 application protocol (S1-AP) identity.
 8. The handover methodaccording to claim 6, wherein the first handover required messagecomprises: an association relationship between the relay UE and theremote UE.
 9. The handover method according to claim 6, wherein thefirst handover required message comprises: identifier information of therelay UE.
 10. A handover method for a relay user equipment (UE) and aremote UE that communicates with a network through the relay UE,comprising: receiving, by a source mobility management entity (MME), ahandover required message from a source evolved NodeB (eNB) of thenetwork serving both the relay UE and the remote UE, wherein thehandover required message comprises a first identifier information ofthe relay UE and identifier information of the remote UE, and thehandover required message is used to instruct a handover of both therelay UE and the remote UE to a target eNB; and sending, by the sourceMME, a mobility management context of the remote UE and a mobilitymanagement context of the relay UE to a target MME to which the targeteNB belongs, to handover both the remote UE and the relay UE to thetarget eNB.
 11. The handover method according to claim 10, wherein thesending, by the source MME, a mobility management context of the remoteUE and a mobility management context of the relay UE to a target MME towhich the target eNB belongs, to handover both the remote UE and therelay UE to the target eNB comprises: sending, by the source MME, afirst redirection request message to the target MME, wherein the firstredirection request message comprises the mobility management context ofthe relay UE and the mobility management context of the remote UE, tohandover both the remote UE and the relay UE to the target eNB.
 12. Thehandover method according to claim 10, wherein the sending, by thesource MME, a mobility management context of the remote UE and amobility management context of the relay UE to a target MME to which thetarget eNB belongs, to handover both the remote UE and the relay UE tothe target eNB comprises: sending, by the source MME, a secondredirection request message to the target MME, wherein the secondredirection request message comprises the mobility management context ofthe relay UE; and sending, by the source MME, a third redirectionrequest message to the target MME, wherein the third redirection requestmessage comprises the mobility management context of the remote UE and asecond identifier information of the relay UE, to handover the remote UEto the target eNB and associate the remote UE with the relay UEcorresponding to the second identifier information of the relay UE. 13.The handover method according to claim 12, wherein the source MME is asource MME of the remote UE and a source MME of the relay UE.
 14. Thehandover method according to claim 10, wherein the sending, by thesource MME, a mobility management context of the remote UE and amobility management context of the relay UE to a target MME to which thetarget eNB belongs, to handover both the remote UE and the relay UE tothe target eNB comprises: sending, by a first source MME, a secondredirection request message to the target MME, wherein the secondredirection request message comprises the mobility management context ofthe relay UE; and sending, by a second source MME, a third redirectionrequest message to the target MME, wherein the third redirection requestmessage comprises the mobility management context of the remote UE and asecond identifier information of the relay UE, to handover the remote UEto the target eNB and associate the remote UE with the relay UEcorresponding to the second identifier information of the relay UE. 15.The handover method according to claim 14, wherein the first source MMEis a source MME of the relay UE and the second source MME is a sourceMME of the remote UE.
 16. The handover method according to claim 10,wherein the first identifier information of the relay UE comprises atleast one of the following: a globally unique temporary identity (GUTI),a system architecture evolution (SAE)-temporary mobile subscriberidentity (S-TMSI), an MME-temporary mobile subscriber identity (M-TMSI),or a UE S1 application protocol (S1-AP) identity.
 17. The handovermethod according to claim 10, wherein the handover required messagefurther comprises group handover indication information, and wherein thehandover method further comprises: determining, by the source MME, thatthe handover of both the relay UE and the remote UE to the target eNB isa group handover based on the group handover indication information. 18.The handover method according to claim 10, wherein the handover requiredmessage further comprises a message type of a message header, andwherein the handover method further comprises: determining, by thesource MME, that the handover of both the relay UE and the remote UE tothe target eNB is a group handover based on the message type of themessage header.
 19. The handover method according to claim 10, whereinthe handover required message further comprises an associationrelationship between the relay UE and the remote UE, and wherein thehandover method further comprises: determining, by the source MME, thatthe handover of both the relay UE and the remote UE to the target eNB isa group handover based on the association relationship between the relayUE and the remote UE.
 20. The handover method according to claim 10,further comprising: obtaining, by the source MME, the second identifierinformation of the relay UE in the third redirection request messagebased on the first identifier information of the relay UE in thehandover required message.